CZ292038B6 - Building element for sealing a hole of a foil of a roof structure - Google Patents

Abstract

The present invention relates to a building element (10, 30) for sealing a hole of a foil of a roof structure wherein the hole is provided with a rectangular backing of a window frame with a predetermined arrangement and dimensions and through which hole access is established from the surroundings into the interior space defined below the roof structure. The invented building element (10, 30), comprises both a rim part (22, 32) defining a central aperture of a configuration and a perimeter substantially corresponding to the configuration and perimeter of said hole, and a collar part (24, 34), integrally connected to and extending substantially perpendicularly from said rim part (22, 32) and circumferentially encircling said central aperture. Said rim part (22, 32) and said collar part (24, 34) are made from weatherproof material. The rim part (22, 32) is adapted to be arranged in substantially co-planar relationship relative to and in facial contact with said foil of said roof structure so as to arrange said central rectangular aperture performed in said rim part (22, 32) in registration with said hole of said foil of said roof structure and so as to arrange said collar part (24, 34) extending upwardly from said rim part (22, 32). The central rectangular aperture in said rim part (22, 32) and said collar part (24, 34) is adapted to the predetermined arrangement and dimensions of the window frame backing so that said collar part (24, 34) circumference is reduced if compared with the backing circumference for producing a hermetic seal between the collar part (24, 34) and the backing. Both the rim part (22, 32) and the collar part (24, 34) are made of flexible and foldable material.

Description

BACKGROUND OF THE INVENTION The present invention relates to a building element for sealing an opening in a foil of a substructure of a roof structure, through which the interior space bounded by the roof structure is accessible from the outside.

BACKGROUND OF THE INVENTION

In modern buildings, the roof is most often constructed of a supporting wooden structure made of rafters and battens, to which tiles or roofing plates are attached. For the hermetic sealing of the interior space bounded by the roof structure, ie under the tiles or roofing plates, a so-called sub-layer or backing is used, which is made of a hermetically sealing and water-impermeable foil, mostly plastic foil. The tiles may be clay or concrete and may have a corrugated surface, the roofing plates may be slate, clay, concrete or metal, for example of steel, copper or aluminum sheets. Provided that the sublayer ensures a permanent hermetic seal, rain, snow or moisture cannot come into contact with the supporting wooden roof structure and damage it. Unfortunately, serious problems arise when it is necessary to make holes in the sublayer, for example for chimneys, windows, ventilation ducts, piping, etc., because the hermetic sealing of the edge of the hole is difficult in most cases and places high demands on the skills of workers.

Certain technical solutions have been described in connection with window frames intended for use in roof structures which employ separate sealing plates which are positioned above and below the aperture in the sublayer, for example as disclosed in Danish Patent Application No. 1232/92. The known prior art solutions, including the technical solution proposed in said published Danish patent application, are not entirely satisfactory for various reasons, firstly because of the impossibility of achieving a reliable and long-lasting seal by known methods, and secondly because these known methods are laborious and demanding and in many cases their use is exceptionally difficult. Various other methods for sealing chimney passages and the like and sealing roofs are known and disclosed in DE 34 42 276, DE 30 32 037, DE 33 21 101, DE 39 22 624, FI 87 250 and US 3,098,663. and the US patent is incorporated herein by reference.

It is therefore an object of the present invention to provide a novel method which makes it possible in a simple and reliable manner to seal an opening in the foil of a roof sublayer with a building element without the need for skilled labor.

Another object of the invention is to provide a novel method for sealing a hole in a foil of a roof substructure which allows long-term sealing by means of a simple and uniform building element.

SUMMARY OF THE INVENTION

The aforementioned objects are achieved by a building element for sealing a hole in a roof structure sheet, wherein the opening is provided with a rectangular window frame support structure of predetermined configuration and dimensions, the opening being an interior space below the roof structure accessible from the outside and a central rectangular hole whose configuration and perimeter substantially correspond to the configuration and perimeter of the aperture; and a collar which is integral with the rim from which it protrudes upwardly and flankes the central rectangular bore, the rim and collar being made of a material resistant to weathering and the rim is adapted for placement in the foil plane of the roof structure and in surface contact

With this foil such that the central rectangular hole in the rim coincides with the opening in the roof structure foil and that the cuff extends upwardly from the rim according to the invention, which is characterized in that the central rectangular hole in the rim and the collar is adapted to a predetermined arrangement and dimensions of the window frame support structure so that the circumference of the collar is reduced compared to the circumference of the support structure to form a hermetic seal between the collar and the support structure, wherein the skirt and collar are made of flexible and foldable material.

The building element according to the invention is a unitary construction which comprises only two parts - a hem and a collar, which are joined together in the central opening of the hem. The building element according to the invention makes it possible to seal the opening in the film of the sublayer by simply placing the flange in the same plane and surface contact with the film of the sublayer and aligning the central opening so as to coincide with the opening in the film. When planks, such as planks to which the window frame is attached, pass through the aperture, the collar of the building element is easily seated relative to the planks of the roof structure, and is preferably tightly secured to planks through the aperture through the aperture. , nails, screws, etc. Placing the skirt of the building element flush with the film of the sublayer may mean that the skirt is either above or below the film of the sublayer, or the arrangement may be a combination of both. If the roof structure is inclined, it is preferred that the portion of the film that is the highest is overlapping the rim, and vice versa that the rim overlaps the portion of the film that is lowest. This ensures that rain, snow or moisture will slide due to gravity on the continuous surface formed by the film of the sublayer and the rim of the building element. The protruding or protruding sleeve prevents snow or water from penetrating into the central opening of the skirt, since the sleeve itself forms a protruding portion of the building member and is also preferably attached to the roof structure planks that extend through the opening in the sublayer.

The parts or parts of the building element are, as mentioned above, made of a weather-resistant material. Since the building element may consist of two parts that are assembled into a uniform construction element during the manufacturing process, the materials of which the parts are made may also differ. Thus, one part of the building element may be made of one material, for example plastic or metal, while the other part may be made of another material, for example another plastic or other metal. According to a preferred embodiment of the invention, however, the hem and the cuff are made of the same material as the weatherproof plastic, for example linear polyethylene, low density polyethylene, polyvinyl chloride, polypropylene or the like, or a corrosion-resistant metal such as aluminum or combinations thereof .

According to alternative production methods, the building element can be made of weldable and castable materials. According to a first embodiment of the building element, the skirt and sleeve are cast from a castable material such as plastic. According to an alternative or second embodiment of the building element according to the invention, the flange and the collar are made of foils which are welded together. If the building element is made of foil, the film materials are preferably flexible and further preferably collapsible, making it possible to produce a building element whose circumference is up to several meters and which nevertheless can be folded into a small plastic bag that is easy to store, transport and later the worker can also be brought to the roof, where after unfolding the building element is attached to the roof structure.

Depending on the particular use of the building element, more specifically the particular arrangement of the opening and the parts that will be fixed in the opening of the substructure of the roof structure, the central opening may have a rectangular, triangular, circular, elliptical or polygonal shape. Most often, however, the building element according to the invention has such an arrangement that the central opening in the rim forms a rectangle. Similarly, depending on the particular use of the building element, the outer edge of the skirt has a rectangular, triangular, circular, elliptical or polygonal shape.

-2 CZ 292038 B6

In order to be able to fasten the cuff so that it fits snugly to the circumference of the boards that pass through the aperture in the sublayer, according to another preferred embodiment of the building element according to the invention, the cuff may converge from the hem to the outer open end of the cuff.

Depending on the particular use of the building element, the sleeve may be inclined according to the requirements of the structure with respect to the rim plane, thus forming a building element for hemming e.g.

According to a preferred embodiment of the building element according to the invention, the building element is adapted to seal a rectangular aperture in the sublayer through which the window frame fixing planks are mounted, which are fixed substantially perpendicularly to the bush defined by the film of the sublayer. Consequently, the collar of the building element according to the invention preferably extends perpendicular to the skirt and is preferably made up of sections or planar elements forming sections which are placed in intimate contact with the wooden planks of the roof structure.

In order to prevent the penetration of water or snow moving down the upper side of the sublayer to which the building element according to the invention is attached by the method according to the invention, i.e. the rim is substantially aligned with the film of the sublayer with which it meets flat The building element according to the invention is further preferably provided with a substantially triangular rim and cuff connecting the transition portion, which is positioned relative to the sublayer in the uppermost part of the building element, extends upwardly from the skirt and forms a barrier for water and snow. The barrier then drains water and snow moving along the upper side of the sublayer to the sides of the central opening in the building element and prevents snow or water from falling into the central opening of the building element, which is determined by the hem of the building element.

According to another alternative embodiment of the building element according to the invention, the building element is a versatile building element which can be adapted to certain predetermined dimensions of the opening in the sublayer. The building element is composed of two halves which together form a building element comprising a skirt and a collar. If the building element according to said preferred embodiment is composed of two halves, the two halves must overlap so that water, snow or moisture cannot find the way of leakage between the two halves, which are assembled into a uniform structure that flanks the perimeter of the aperture in the sublayer.

According to a further preferred embodiment of the building element according to the invention, the building element comprises fastening means for fastening the skirt to the structural elements of the roof structure. The fastening means may be a plate that is fastened to the structural elements of the roof structure, for example by means of a nail, screw or similar fastener, or alternatively a hook-shaped fastener for snapping around the structural element of the roof structure.

According to another alternative embodiment of the building element according to the invention, the building element comprises a collar that is attached to the cuff or attached around the circumference of the cuff such that the film of the sublayer is clamped between the cuff and the collar. The collar building member forms an assembly in which the aperture of the sublayer is sealed by the cooperation of a collar and a separate collar between which the film is clamped. The building element may further comprise an O-ring which is inserted and pressed between the collar and the collar.

Depending on the embodiment, the separate collar may be provided with internal detachable ribs, which form the cutting guides.

According to an alternative embodiment of the building element, the O-ring may fit into a recess along the circumference of the collar or flange, or alternatively into the recess around the periphery of the collar.

-3 CZ 292038 B6

According to another embodiment, the skirt may have deformable straps for attaching the skirt to the battens by bending the strips from the skirt plane. Preferably, the skirt may have apertures for extending a portion of the bands. The skirt may have first and second plates, the strap being attached to the second plate by a hinge.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be further described with reference to the drawings, in which the individual figures show:

Fig. 1 is a perspective view of a first preferred embodiment of a building element according to the invention.

Fig. 2 is a perspective view, similar to Fig. 1, of a second embodiment of a building component according to the invention.

Fig. 3 is a perspective view and a partial cross-sectional view of an element illustrating a method of using the first embodiment of the building element of Fig. 1 in the roof structure to which the element is attached and sealing the opening in the substructure of the roof structure.

Fig. 4 is a perspective view similar to Fig. 3 showing a method of using a third embodiment of a building component of the invention in a roof structure.

Fig. 5 is a perspective view, similar to Figs. 3 and 4, of a fourth embodiment of a building element according to the invention, which resembles the first embodiment of Figs. 1 and 3 and illustrates a method of trimming the element at the point of use.

Fig. 6 is a perspective view showing a method of using a fifth embodiment of a building element of the invention to seal a chimney passing through a roof of a building structure.

Fig. 7 is a cross-sectional view of a roof structure with tiles attached to support battens to which a sixth embodiment of a building element according to the invention is used to seal an opening in the roof structure sublayer which allows the sub-layer and tile to be discharged.

Fig. 8 is a sectional view similar to Fig. 7 showing a slightly modified use of the element of Fig. 7.

Fig. 9 is a perspective view and a partial cross-sectional view of an element illustrating the use of the building element of Figures 7 and 8, particularly the fastening of the building element of Fig. 8 to a supporting roof structure, sealing the opening in the substructure of the roof structure.

Fig. 10 is a perspective view of a seventh embodiment of a building element according to the invention.

Figures 11 and 12 are perspective views of a first portion of a seventh embodiment of the element of Figure 10.

Fig. 13 is a perspective view illustrating a first step of a method of attaching a seventh embodiment of a building element to a roof structure, sealing an opening in the roof structure sublayer that allows the sub-layer and tile to exit a circular air conditioning element.

Fig. 14 is a perspective cross-sectional view showing the outer rim of the seventh embodiment of the uniform cuff or hemming element of Fig. 10 and illustrating the adaptability of the uniform cuff or hemming element.

Fig. 15 is a perspective view showing a second step of the method of securing the seventh embodiment of the building of Fig. 10 to the roof structure.

-4GB 292038 B6

Fig. 16 is a perspective view similar to Fig. 15 showing the final step of the method of securing the seventh embodiment of the building element of Fig. 10 to the roof structure.

Fig. 17 is a top perspective view of an eighth embodiment of a building element of the invention that differs slightly from the preferred embodiment of Fig. 1.

Fig. 18 is a bottom perspective view of the eighth embodiment of the building element of Fig. 17.

DETAILED DESCRIPTION OF THE INVENTION

Fig. 1 shows a first preferred embodiment of a building element 10 according to the invention. The building element 10 is made of a heat-sealable film, such as polyethylene, for example linear polyethylene or low density polyethylene, or other weather resistant material, for example aluminum foil, polyvinyl or polypropylene film, or a combination of these materials. The building element 10 comprises a total of four foil sections 12, 14, 16 and 18 which form two pairs. The first pair comprises foil sections 12 and 16, and the second pair comprises foil sections 14 and 18. The foil sections 12 and 16 of the first pair of foil elements are disposed symmetrically with respect to the imaginary centerline 20 of the building element 10, and the foil sections 14 and 18 of the second foil pair The film sections 12 and 14 are welded together in the weld joint 13. Similarly, the film sections 14 and 16, the film sections 16 and 18 and the film sections 12 and 18 are welded together in the weld joints. 15,17 and 19.

The building element 10 is a structure that includes a substantially planar peripheral skirt, which consists of the main portions of the film sections 12, 14, 16 and 18, and which forms a plane to which the imaginary centerline 20 is perpendicular. The unitary construction of the building member 10 further comprises a collar formed by the vertical portions of the film sections 12, 14, 16 and 18 and which encloses a substantially rectangular center hole in the building member 10 centered by an imaginary centerline 20 in the center. recognize the rim 22 and the collar 24 of the structural member 10.

As mentioned above, the building member 10 is preferably made of a foil, such as a plastic film, which can either be shaped into the overall shape of the building member 10 by applying heat to the heat-shrinkable material, or alternatively the building member 10 can be formed by a combination of heat shrinking processes. and welding, wherein the four separate foil sections are welded together, shrinking into the overall shape of the structural member 10 and further trimmed along the outer edge 26 to form an overall rectangular outer border and along the upper edge 28 of the sleeve 24.

The building element 10 shown in FIG. 1 is used, as will be described in more detail with reference to FIG. 3, to seal the opening in the roof structure, which can be used to mount, for example, a window frame, chimney, air conditioning element, and the like.

Fig. 2 shows a second embodiment of a building element 30 according to the invention. The second embodiment of the building element 30 differs from the above-described first embodiment of the building element 10 in that the building element 30 is made as a uniform casting, for example, of linear polyethylene or a similar plastic material, or of a suitable metal material such as aluminum. The element comprises an outer skirt 32 and a collar 34 that are similar to the skirt 22 and the skirt 24 of the building element 10 of Fig. 1. The skirt 32, as described above, forms an outer edge 36 of substantially rectangular shape. The skirt 32 is a planar structure from which the sleeve 34 forming a rectangular shaped upper edge 38 extends substantially perpendicularly upward. The collar 34 and rim 32 are joined together in a rectangular joint 40 which, with the slightest variation necessary to allow removal of the structural member 30 from the casting mold, corresponds to the rectangular shape of the upper edge 38 of the collar 34. The second embodiment of the structural member 30 may be construction

The sleeve 34 and the like sleeve 24 will be angled inwardly so that the periphery of the top edge will be smaller than the periphery of the joint 40. The skirt 32 may be made in any suitable shape, such as a square , a circle, a triangle, or even a curved configuration, to accommodate the building element 10, 30 for a particular application that requires the building element 10, 30 to have a shape different from that shown in Figures 1 and 2.

The various uses of the building element according to the invention are shown in Figures 3 to 6, which also show an alternative embodiment of the building element. In Fig. 3, a first embodiment of building element 10 is attached to a roof structure that includes two vertical or angled strips 50, 52 on which a sublayer or backing is attached. The sublayer comprises three strips 54, and 58 which are substantially horizontal with respect to the roof structure and overlap one another so that the sublayer stripe 54, which is located above the sublayer strips 56 and 58, overlaps with its lower portion the adjacent sublayer strut 56 in a similar configuration, the lowermost portion overlaps an adjacent web layer 58 of the sublayer. Between the bars 50 and 52 is a wooden 15 support frame structure that includes four substantially perpendicular planks 60, 62, 64 and 66. The planks 60, 62, 64 and 66 extend through the film of the sublayer to form an aperture through which the structures will pass. According to the initially intended use of the first embodiment of the building element 10 according to the invention, the window frame is attached to a wooden support frame structure comprising four planks 60, 62, 64, 20 and 66. The building element 10 serves for a hermetic seal. sealing the timber support frame, which includes planks 60, 62, 64, and 66, to the sublayer that includes sheets of film 54, 56, and 58, to prevent rain, snow or moisture from penetrating the timber support frame and possibly into the roof a structure that includes moldings 50 and 52 along the edges of the boards 60, 62, 64 and 66 where water, snow or moisture would t could be the cause of rot or attack of the elements of the roof structure, 25 for example by moldings 50 and 52, by a fungus.

As can be seen in FIG. 3, the upper portion of the building element 10, i.e. the foil section 18, is positioned below the sublayer web 54, while the foil section 14 of the building element 10 overlaps the sublayer web 58. This achieves the same overlapping configuration between the building member 10 and the sublayer as between the sublayer strips 30, allowing water, moisture or snow to move down the upper side of the sublayer from the highest web 54 to the adjacent web 56 and beyond the sublayer surface without she penetrated beneath her. When the building element 10 is intended to be used in conjunction with a window frame, which usually has a certain predetermined arrangement of certain predetermined dimensions, the building element 10 is adapted to the arrangement and dimensions of the window frame structure. The outer periphery of the upper edge 28 35 of the collar 24 of the structural member 10 corresponds to the outer periphery of a timber support frame structure that includes planks 60, 62, 64 and 66. The structural member 10 has an inner side for hermetic contact between the outer sides of the planks 60, 62, 64 and 66a. the collars 24 of the structural member 10 as compared to the outer periphery of the timber support frame structure have somewhat reduced dimensions. Since the building member 10 is intended to be closely adjacent to the boards 60, 62, 64 and 66 and by this close contact 40 foil portions 12, 14, 16 and 18 slightly deform, this will increase the circumference of the upper edge 28 of the sleeve 24 of the building member. The element 10 is preferably fastened to the boards by means of nails, cracks, screws, glue and the like.

Alternatively, the foil material of the building element 10 may be heat shrinkable. In this case, the building element 10 is fastened to the planks 60, 62, 64 and 66 by shrinkage, or so-called recovery, of the sleeve 24 of the building element 10 under the effect of heat emitted by the gas firing unit, electric hot air fan or the like. pipe insulation. The outer circumferential rim 22 of the building element 10 can, if appropriate, be sealed to the sublayer strips 54, 56 and 58 by sealing tape or glue.

In Fig. 3 two elements of the construction of the window frame 68 and 70 are shown. The frame elements 68 and 70 both have a substantially rectangular shape and are made of L-profiles, for example drawn aluminum profiles. The frame member 68 is an inner sealing frame which is secured, for example, by nails or screws, to the outside of the boards 60, 62, 64 and 66 such that the foil of the collar 24

The component 10 is clamped between the frame and the boards. The frame member 70 overlaps, as shown in FIG. 3, the frame member 68. The frame member 70 is attached to the upper edge of the boards 60,

Of course, in conjunction with the building element 10 of the invention, alternative frame structures may also be used to seal, for example, a window frame to the building element and further to the roof substructure.

In Fig. 4, the strips 50 and 52 of the sublayer strips 54, 54 and 56, and the planks 60, 62, 64 and 66 are shown together with a slightly modified third embodiment of the building element 30 'according to the invention which is a modified second embodiment of the building element described above. The third embodiment of the building element 30 'is made simply by cutting the second embodiment of the building element 30 into two substantially identical parts, which allows the longitudinal dimension of the building element 30' to be adapted to the length of the planks 60 and 64. 31 'and 33'. When using two parts 31 'and 33' of the building element 30 ', the part 311' overlaps the part 33 ', since, as is apparent from Fig. 4, it is fixed ahead of the part 33'. The two parts 31 'and 33' of the third embodiment of the building element 30 'may, as shown in Fig. 3 above, be attached to the boards 60, 62, 64 and 66 to which the window frame structure is attached, for example, preferably by nails or screws.

FIG. 5 shows a slightly modified fourth embodiment of a building element according to the invention, which is a modification of the first and preferred embodiment of the building element 10 described above. This fourth embodiment of FIG. The building element 10 ', like the first and preferred embodiments of the building element 10 described above, is made of a foil, such as a flexible foil, for example of polyethylene. However, it differs from the first and preferred embodiments of the building element 10 described above in that it has increased dimensions of its parts. The designation of the elements or parts of the construction element 10 'in FIG. 5 corresponds to the marking index used in FIG. 1. The alternative construction element 10' differs from the first construction element 10 described above in that the skirt 22 'and the collar 24' are enlarged over corresponding elements or portions of the first and preferred embodiments of the building member 10 to allow the collar 22 'and collar 24' to be adapted to the exact size by cutting off excess material from the collar 22 'and collar 24' as indicated by flaps 21 'and 23' are cut or separated from the skirt 22 '. and like flaps 25 'and 27'. The somewhat increased dimensions of the skirt 22 'and the skirt 24' of the building element 10 'allow adaptation or cutting of the building element 10' for a given application. The building element 10 'is preferably made of a heat-shrinkable film that allows overall adaptation of the building element 10' for a given application by heat shrinking the building element 10 'to ensure a perfect fit of the film to the support boards 60, 62, 64 and 66, and of excess material of collar 22 'and collar 24'.

Fig. 6 shows an alternative use of a fifth embodiment of a building element according to the invention. This fifth embodiment of the building element of the present invention is designated as a whole by 80 and is used to seal the passage of the chimney 90 through the roof sublayer 92, which is composed of corrugated tiles laid in a conventional manner overlapping each other. The building element 80 has a construction generally similar to that of the second embodiment of the building element 30 described above in Figure 2, and is preferably made as a plastic casting, for example, of linear polyethylene. The element comprises a rim 82 similar to the rim 32 of the aforementioned structural element 30 and a collar 84 similar to the collar 34 of the aforementioned structural element 30. Unlike the structural element 30, where the cuff 34 extends substantially perpendicularly upwardly from the rim 32, the substantially planar rim 82 is an angle that differs from 90 °. The angle formed between the collar 84 and the rim 82 is determined by the slope of the roof surface 92 so as to provide a perfect sealing contact between the collar 84 and the surface of the outside of the chimney 90 and the like. to seal the contact between the upper edge of the sleeve 84 and the outer surface of the chimney 90, plates 86 and 88 are secured to the outer surface of the chimney 90, which overlap the sleeve 84 of the element 80.

In contrast to the above-described first, second, third, fourth and fifth embodiments of a building element according to the invention, which comprise one part consisting exclusively of a hem and a collar, it has another

A sixth embodiment of a building element according to the invention, which will be described below with reference to FIGS. 7 to 9, has an added sealing element which, together with the sleeve or flange element, forms a sealing assembly. Vertical and cross-sectional views of the roof structure of Figs. 7 and 8 show two alternative uses of a collar or edging element or assembly in conjunction with a roof that is covered with individually stacked corrugated tiles or roofing plates, for example, baked tiles or tiles of concrete or the like.

In Figures 7 and 8, the rafters 94 of the roof structure are shown to which a foil layer 96 is fastened. Parallel and transverse battens are attached to the upper edge of the rafter 94 and the other rafters of the roof structure. The battens 98 are parallel to the rafter 94 and the battens 100 and 102 are transverse to the rafter 94 The battens 98 are additionally horizontal to the roof structure. The battens 100 and 102 are spaced apart, and their primary task is to support the overlapping corrugated tiles 104, 106 and 108. The bags 104, 106 and 108, as well as the conventional tiles, have a tooth at the top to grip the support battens, e.g. and 102.

The building element 110 of FIGS. 7 and 8 serves to hermetically seal the opening in the sublayer 96 and in the roof structure through which a channel 140, for example an air duct, passes from inside the building to the environment. In Figure 7, the channel 140 extends through the roof structure substantially perpendicular to the exterior surface of the roof formed by the tiles 104, 106 and 108. whereas in Figure 8 the channel 140 extends through the opening in the roof substantially vertically at an angle other than 90 ° relative to the above defined the external surface of the roof. Adapting the angular position of the channel 140 relative to the vertical axis and relative to the exterior surface of the roof is easily accomplished by moving the building member 110 from the position shown in FIG. 7 to the position of FIG. 8, which differ from each other in that FIG. element 110 is fastened over the hinge part of the assembly, which will be described in more detail below, to the upper edge of the lath 102. whereas in Fig. 8, the building element 110 is fastened over the hinge portion to the lower edge of the lath 102. having the appropriate experience in the art will be readily set by simply placing a separate bar parallel to the battens 100 and 102 and attaching the building element 110 to this bar. The construction of the building member 110 will now be described in more detail in Fig. 9, which illustrates a building member 110 seated relative to the sublayer 96 and attached to the bottom edge of the slat 102 of Fig. 8.

The component 110 includes two portions 112 and 114 that are placed on the top and bottom of the sublayer 96, respectively. The component 112 has a construction similar to that of the above described embodiments of the component and includes a peripheral hem 116 and a collar 118. building element 110, and also element 112, a plate-shaped segment 120 from which two additional plates 122 and 124 extend upward. The height of the plates 122 and 124 corresponds to the height of the battens on which the battens 100 and 102 are fastened, i.e. From the plates 122 and 124, two triangular plates 126 and 128 extend parallel to the plate segment 120 and terminate in two suspension plates 130 and 132 forming the above-mentioned suspension part, by means of which, for example, nails or screws 7 and 8, there is shown one nail 134 which extends through one from the holes in the hinge plates 130 and 132 and is fixed in a conventional manner by a hammer. In addition to keeping the plate segment 120 at a desired distance below the plates 126 and 128, the plates 122 and 124 also serve as a water and snow barrier, which carries water and snow moving along the upper side of the sublayer 96 to the opening side of the building member 110 and prevents snow or water from falling into the hole.

The rim 116 and the collar 118 of the element 112 are joined at a joint that forms a peripheral recess into which the O-ring fits. The collar 118 of the element 112 further has through holes 138 into which the hooks of the bottom member 114 of the building member 110 will engage, thereby locking the two parts 112 and 114 together in a tight and locked position. The part 114 has a construction that resembles the construction of the building element according to the invention described above in Figures 1 to 6 and which comprises

292038 B6 the peripheral rim 142 and the peripheral collar 144 extending upwardly from the rim 142. The collar 144 has, as discussed above, hooks 146 that engage the holes 138 of the collar 118 of the component 112.

The building member 110 is fixed to the designated position as follows. First, the member 112 is placed in a predetermined position relative to the roof structure and then relative to the sublayer 96 and secured to the batten 102 by nails or screws as described above. The upper member 112 is positioned, as will be appreciated, in the middle of the unsupported sublayer 96, while the above-described embodiments of the building element of Figures 1 to 6 are supported in position by a roof structure, for example strips 50 and 52 of Figures 3 and 4. of the upper portion 112 with the central opening in the collar 118 of the portion 112 cut through the opening in the sublayer 96 to insert the portion 114 from above, rotate, press against the underside of the sublayer 96 and the cuff hooks 144 of the lower portion 114 The topsheet 112 is locked in position relative to the topsheet 112 as described above. After locking the bottomsheet 114 in position, the film of the sublayer 96 is pressed between the flanges and cuffs of the topsheet and the bottomsheets 112 and 114. the excess foil coming out of the assembly can be easily cut off to create a perfect looking and hermetic The aperture sealed aperture in the sublayer 96 which is further resistant to water and snow due to the angled plates 122 and 124 described above. A hermetic seal between a channel such as channel 140 of Figures 7 and 8 and between the building member 110 is readily achieved, if desired, for example by means of seals, sealing foils and tapes in a manner that will be apparent to those having appropriate experience in the art. . However, in many applications, a hermetic seal between an element that passes through the building element 110, such as the channel 140 of Figs. 7 and 8, and the building element 110 is not necessary and is therefore omitted.

Referring now to Fig. 10, a structural member 210 is shown which is a seventh embodiment of a structural member of the invention. The building element 210 serves to hermetically seal the opening in the sublayer through which a channel, such as an air channel, passes from the interior of the building and through the opening in the roof structure to the surrounding environment. Building element 210 essentially represents an alternative embodiment of building element 110 as described above in Figures 7 and 8. The building element 210 comprises, similar to the building element 110 described above, two separate parts or elements. The collar member 212 forms the top of the assembly and serves substantially the same purpose as the above-described member 112. Similarly, the collar member 214 forms a lower panel that is similar to the above described member 114 of the sixth embodiment of the building member 110 described in FIGS. the element 212 includes a peripheral skirt 216 and a collar 218. The collar 218 extends in opposite directions to the upper end and the lower end of the baffle assembly 217 and 219. The skirt 216 has a plate 220 at the top of the building element 210, as well as a collar element 212. two additional plates 222 and 224 extend upwardly. The plates 220 and 224 are similar to elements 122 and 124 of the component 110 described above and are connected to two substantially triangular plates 226 and 228 parallel to the rim 216. Similar to elements 122, 124, 126 and 128 of the building element 110 serve the elements 222, 224, 226 and 228 mainly as a barrier, preventing water and snow from fell into the opening formed by the rim 218 of the structural member 210.

However, the building element 210 differs from the building element 110 described above in that the building element 210 has a structure which makes it easy to use the assembly on roof structures of different dimensions, particularly on roof structures of different distances substantially from the roof structure with horizontal battens. 9. Due to this flexibility, the collar member 212 has two additional plates extending from the outer edge of the skirt 216 parallel to the baffles 217 and 219 to a height above the skirt 216 that is equal to the height of the baffles 217 and 219. From the plates 230 and 232, which are substantially vertical, two plates 234 and 236 extend outwardly from the outer edge of the plates. The plates 234 and 236 are parallel to and above the skirt 216 as shown in Figure 10. The plates 234 and 236 comprise through holes 238 and 240. The structural member 210 further comprises two elongate strips 242 and 244, respectively The hinges 242 and 244 comprise through holes 250 and 252 for nails or screws by which the collar member 212 is fastened to the roof structure, as will be described in more detail below.

-9EN 292038 B6

11 and 12, the lower collar element 214 of the structural member 210 is shown in more detail. The collar element 214 consists essentially of two portions, such as a flange 260 and a collar 262. A collar 262 is formed in the collar 262 into which four detachable ribs 264 are formed in the plane defined by the collar 260 forming the opening 268. As will become apparent hereinafter , the ribs 264 form a cutting guide. From the upper edge of the collar 262 a plurality of locks 266 are provided to secure the collar element 214 in position relative to the collar element 212 after the collar element 214 is inserted into the collar element 212 of the building element 210 of FIG. 10.

13 and 14, two assembly steps of building element 210 are shown. In the first assembly step of building element 210, collar element 214 is placed in the intended position relative to the belt of sublayer 96 of FIG. 13. Next, a knife 280 or similar cutting means is used to cut through. of the opening in the sublayer 96 along the cut line 282 that corresponds to the inner edge of the ribs 264 of the flange 260 of the collar element 214. As shown in FIG. 13, the portion of the sublayer 96 that is separated by a knife is designated 284. which are an integral part of the assembly, ensure that the aperture in the sublayer 96 formed by cutting is accurate. After cutting the hole in the sublayer 96, the ribs 264 are separated from the main portion of the collar element 214 simply by breaking along the separating lines shown in Figures 11 and 12.

Upon completion of the operation of FIG. 13, the upper collar member 212 of the building member 210 is ready for use in the operation of FIG. 14. The elongate strips 242 and 244 on the collar member 212 are bent down, the outer ends of the elongate strips 242 and 244 are inserted into corresponding holes. in plates 234 and 236 and stretch through them. At this stage of inserting and extending the outer ends of the elongated strips through the corresponding openings in the plates 234 and 236, the collar member 212 is adapted to position the aperture in the sublayer 96 resulting from the procedure described above in Fig. 13. 15, where the batten 102 is shown together with the dashed lath 100. By bending the elongated strips 242 and 244 downward from the outwardly extending plates 234 and 236 and extending the outer ends of the elongated strips 242 and 244 through certain openings in the plates 234 and 236 a total of four hinge points 254, 256, 255 and 257. hinge points 254, 256, 255, and 257 formed from the elongate strip 244 are designated 254 and 256 hinge points formed from the elongated strip 242 then 255 and 257.

After aligning or adjusting the structural member 210 with respect to the roof structure and opening in the sub-layer 96, the collar member 212 is secured to the roof structure as shown in Figure 15. Nails or bolts are threaded through one or more holes of the hinge locations 256 and 257; attached to an adjacent lath 102. In Fig. 15, two nails that attach the hinge locations 256 and 257 are designated 258 and 259. Similarly, the hinge locations 254 and 255 are attached to the lath 100 by other nails, screws or similar fastening means.

As is apparent from FIG. 15, the sublayer 96 forms a peripheral flap 286 which has been formed as described in FIG. 13 by cutting the aperture in the sublayer 96 along the outer edge of the separable ribs 264 of the collar element 214. by collar 218 of collar member 212, accurate dimensions as well as proper placement, since collar member 212 aligns or adapts to the dimensions of the roof structure and hole position in the sublayer 96, as described above with reference to FIGS. 14 and 15.

Finally, the collar member 214 is inserted and pressed into the opening defined by the collar 218 of the collar member 212 from the roof interior as shown in FIG. 16. At the stage of pressing the collar element 214 into the through hole defined by the collar 218 of the collar member 212, by collars 262 and 218 of parts 214 and 212 to form a connection between the sub-layer 96 and the building member 210. After the collar element 214 has been pushed into the collar element 212, the locks 266 position the collar element 214 relative to the collar element 212 via a bayonet connection to hold the collar 10 and 16 with respect to the collar member 212 of the building member 210.

-10GB 292038 B6

Figures 17 and 18 show an eighth and highly preferred embodiment of a building element of the invention, designated 310. Essentially, the eighth embodiment 310 is a modified embodiment of the first and second embodiments of Figures 1 and 2 described above, and further includes features of the sixth 7 to 9 and 10 to 16. The eighth embodiment of building element 310 is a unitary cast element made, for example, of linear polyethylene or a similar plastic material, or of a corresponding metal such as aluminum. The building member 310 comprises a plurality of foil portions, such as four foil sections 312, 314, 316, and 318, which are entirely cast foil sections similar to the four foil sections 12, 14, 16 and 18 of the building element 10 described in Figure 1. a316 forms the sides, and the film sections 314 and 318 are the lower and upper sections, wherein the terms lower section, upper section, and sides refer to the intended orientation of the building element 310. The building element 310 further includes two end foil sections 315 and 319 that integrally follow the lower and upper foil sections 314 and 318 by means of weakened or hinged sections 313 and 317. which allow the overall length of the element 310 to be adapted to the application by bending the end foil sections 315 and 319 or separating them from adjacent lower and upper sections 314 and 318. 315 and 319 with respect to the lower and upper foil sections 314 and 318 bent, the end foil portions may be used to secure the element 310 to the roof battens, such as the batten 102 of FIGS. 7 and 8, for example with nails, screws and the like.

The foil sections 312, 314, 316 and 318 described above form an integral rim 322 of the structural member 310 from which an upwardly cast collar 322 extends upwardly to form a rim for attachment to the timber roof structure and sealing the perimeter of the timber roof structure as described 3 and 4. The cuff 324 defines an upper or outer peripheral edge 326 of a generally rectangular shape.

1 and 2, which are generally symmetrical, the eighth embodiment comprises the aforementioned lower and upper foil sections 314 and 318 and hence a predetermined orientation. Thus, while the lower foil section 314 is substantially planar, the upper foil section 318 comprises a raised portion of a triangular shape that is formed by upwardly extending plates 332 and 334 and a planar plate of triangular shape 330. The plates 330, 332 and 334 serve substantially the same purpose. 7 to 9, i.e., the drainage of snow and water.

FIG. 17 is a top view of the building member 310; FIG. 18 is a bottom view of the building member 310 showing a recess 328 that forms the above-described triangular rain and snow barrier with plates 330, 332 and 334. which prevents water and snow moving along the upper side of the sublayer, such as sublayers 56 and 58 of Figs. 3 and 4, from falling into the central opening of the building element, which is determined by the upwardly extending cuff 324 of building element 310, and hillside.

Example 1

The prototype of the above-described first embodiment of the building element 10 described above in FIG. 1 was made of four foil sections 12, 14, 16 and 18 of conventional polyethylene 0.5 mm thick, welded together in the weld joints 13, 15, 17 and 19. and forming an overall rectangular outer boundary of dimensions 176 cm x 129 cm. The foil sections 12, 14, 16 and 18 were shaped into the configuration of FIG. 1 during welding. The height of the upwardly extending cuff 24 was 16 cm and the dimensions of the central opening determined by the top edge of the cuff 24 was 98 cm x 80 cm. The central opening in the building member 10 was positioned centrally relative to the outer boundary.

- 11 GB 292038 B6

Example 2

The prototype of the above-described second embodiment of the building element 30 described above in Fig. 2 was cast from linear polyethylene. The element had an arrangement similar to that of FIG. 2 with an outer boundary 36 of 117 cm x 95 cm. In the middle of the plate-shaped rim 32 was an opening of 98 cm x 78 cm and the collar 34 extended substantially perpendicular to the plane of the rim 32 up to 8 cm above the upper surface of the rim 32 of the building element 30.

Example 3

A prototype of the eighth embodiment of the uniform collar or flange member 310 described above of Figures 17 and 18 was cast from linear polyethylene. The element had an arrangement similar to that of FIGS. 17 and 18 and had an outer boundary of 1950 mm x 1178 mm. The film segments 315 and 319 each measured 1178 mm x 150 mm. In the middle of the flange 322 of the fully cast component 310, the outer edge 326 of the collar 324 was a bounded aperture of 1398 mm x 778 mm. The height of the barrier provided by the plates 330, 332 and 334, i.e. the height of the triangular barrier, measured from the upwardly extending cuff 324 was 70 mm, and the triangular plate 330 was raised 20 mm above the plane determined by the upper foil section 318 of flange 322.

Although the invention has been described above with reference to various preferred embodiments, various modifications will be apparent to one of ordinary skill in the art to be considered as part of the invention according to the foregoing claims. Although the invention has been described above with reference to rectangular shaped apertures and the cuffs of the above-described building elements have been described in connection with rectangular apertures such as rectangular apertures for fitting roof window frames, the building element of the invention is not limited to sealing the rectangular apertures. the collar of the building element according to the invention may be made in any arrangement meeting specified requirements, i.e. it may be circular, rectangular, triangular, square, elliptical or comprising straight and curved sections or a combination of said geometric shapes.

PATENT CLAIMS

Claims (21)

A building member (10, 30) for sealing an aperture in a roof structure sheet, wherein the aperture is provided with a rectangular window frame support structure having a predetermined configuration and dimensions, the aperture being an interior space below the roof structure accessible from the outside and the building member (10, 30). ) comprises, on the one hand, a skirt (22, 32) which delimits a central rectangular bore whose configuration and circumference substantially correspond to the configuration and circumference of the aperture, and, on the other hand, a sleeve (24, 34) which is integral with the skirt (22, 32). the edge (22, 32) and the collar (24, 34) are made of a weather-resistant material and the edge (22,32) is adapted to be placed in the plane of the roof structure foil and in flat contact with the film so that the central rectangular hole in the rim (22, 32) coincides with the opening in the roof structure film and that the collar (24, 34) extends it was going up from the hem (22, 32), - 12GB 292038 B6, characterized in that the central rectangular hole in the rim (22, 32) and the collar (24, 34) is adapted to a predetermined arrangement and dimensions of the window frame support structure so that the circumference of the collar (24, 34) is reduced in compared to the periphery of the support structure to form a hermetic seal between the collar (24, 34) and the support structure, wherein the skirt (22, 32) and the collar (24, 34) are made of a flexible and foldable material. Building element (10, 30) according to claim 1, characterized in that the rim (22, 32) and the sleeve (24, 34) are made of the same material which is weather-resistant plastic, in particular high-density polyethylene, low-density polyethylene, polyvinyl chloride, polypropylene and the like, or of a corrosion-resistant metal, in particular of aluminum, or a combination thereof. The building element (10, 30) according to any one of claims 1 and 2, characterized in that the rim (22, 32) and the collar (24, 34) are cast from a castable material. The building element (10, 30) according to any one of claims 1 to 3, characterized in that the rim (22, 32) and the collar (24, 34) are made of foils that are welded together. The building element (10, 30) according to claims 1 to 4, characterized in that the sleeve (24, 34) tapers in the direction from the rim (22, 32) to its open end. A building element (10, 30) according to any one of claims 1 to 5, characterized in that the rim (22, 32) defines a plane and the collar (24, 34) is inclined relative to this plane. A building element (10, 30) according to any one of claims 1 to 4, characterized in that the sleeve (24,34) is arranged perpendicular to the rim (22, 32). The building element (10, 30) according to any one of claims 1 to 7, characterized in that the sleeve (24, 34) consists of planar element segments (12,14,16, 18). A building element (30 ') according to any one of claims 1 to 8, characterized in that a substantially triangular transition portion (330, 332, 334) extends upwardly between the skirt (322) and the sleeve (324). from the rim (322) and forms a barrier for rain or snow. A building element (30 ') according to any one of claims 1 to 9, characterized in that it consists of two halves (3', 33 ') which together form a building element (30') comprising a skirt and a collar. A building element as claimed in any one of claims 1 to 10, further comprising fastening means (120, 122, 124, 126, 128, 130, 132) for attaching the rim (116) to the structural element (102) of the roof structure. . A building element according to claim 11, characterized in that the fastening means (120, 122, 124, 126, 128, 130, 132) form a plate-like segment (120) which extends perpendicularly to the bad (116) and which is provided with an opening for a nail, screw or similar fastening means for attaching the plate-like segment (120) to the structural member (102) of the roof structure. A building element according to claim 11, characterized in that the fastening means (120, 122, 124, 126, 128, 130, 132) are formed by a hook-like fastener for locking around the structural element (102) of the roof structure. - 13 GB 292038 B6 The building element (210) of claim 11, wherein the skirt comprises a strap (242, 244) forming a fastener, wherein the strap (242, 244) is disposed on the side of the skirt and is deformable to protrude from the plane of the skirt. . The building element (210) of claim 14, wherein the skirt comprises openings (238,240) for threading the deformed strip (242, 244). The building element (210) of claim 14, wherein the skirt comprises a vertically oriented first skirt (230, 232) extending from the side of the skirt and a second skirt (234,236) extending parallel to the skirt of the first skirt (230, 232). with apertures (238, 240), the second flange (234,236) being provided with a hinge (246,248) supporting the band (242, 244). The building element of any one of claims 14 to 16, further comprising a separate collar element (214) for attachment to the collar element (212) for clamping the roof structure foil between the collar element (212) and the collar element (214). The building element of claim 17, wherein the separate collar element (214) has detachable ribs (264) extending inwardly in a plane defined by the skirt (260). A building element according to claim 17 or 18, characterized in that an O-ring is inserted between the collar element (212) and the collar element (214). 20. The building element of claim 19, wherein the O-ring is inserted into a circumferential groove in the collar element (212) or in the rim (260). The building element of claim 19, wherein the O-ring is inserted into a circumferential groove in the collar element (214). 10 drawings