AT13303U1 - Screw for roof construction - Google Patents

Abstract

Screw (1) for fastening waterproofing membranes (25), in particular of bitumen, on non-nailable constructions, in particular thermal insulation elements (26), as a component of a roof construction with a screw shank (2), a thread (3) running on the screw shank (2) and a screw head (4) having an outer surface (5) and an inner surface (6) facing the screw shaft (2). On the one hand to dispense with the use of nail planks and on the other hand to avoid moisture or air entrapment, it is provided according to the invention that the outer surface (5) in the direction of the screw shaft (2) curved outer surface portion (5a) and the inner surface (6 ) has a curved in the direction of the screw shaft (2) inner surface portion (6a) and that a tangent (29) to the outer (5) surface portion at a point of an outer boundary edge (7) with a tangent (30) to the inner surface portion ( 6) includes an acute angle (8) at a point of an inner boundary edge (28).

Description

Austrian Patent Office AT 13 303 Ul 2013-10-15

description

SCREEN FOR ROOF CONSTRUCTION FIELD OF THE INVENTION

The present invention relates to a screw for fastening waterproofing membranes, in particular made of bitumen, non-nailable structures, in particular thermal insulation elements, as part of a roof construction with a screw shank, a thread running on the screw shank and a screw head with an outer surface and an inner, to the screw shaft facing surface.

STATE OF THE ART

In roof structures, which are sealed by means of waterproofing membranes or roofing membranes, in particular bituminous membranes, often raises the problem, the bituminous membranes to underlying, not nailable constructions, for example, to heat insulation elements, sufficiently secure. It should be noted in particular that the bitumen membranes are secured both parallel and normal to the roof surface or eaves edge. The securing parallel to the roof surface or eaves edge prevents slipping and, if necessary, wave formation, which occurs e.g. due to the roof inclination, caused by temperature fluctuations or snow-related shear loads. The protection normal to the roof surface or eaves edge also prevents abrasion of the bituminous membranes by wind suction. It should be noted that the underlying structures are in any case in their turn sufficiently connected to a substructure.

On sloping roofs from about 3 ° or 5% roof pitch roofing membranes are mechanically fixed according to the common teaching in a relatively complex process, see. e.g. the standard work "Technical rules for the planning and execution of waterproofing with polymer bitumen and bitumen membranes", 3rd edition, ISBN 978-39801831-8-5. Here, nail planks are arranged on each web subdivision as well as on eaves and ridge. If there is a thermal barrier coating, the nail planks are to be incorporated into this thermal barrier coating. The webs of the individual waterproofing layers, which are laid in the eaves-first direction, must be cut to length on each nail plank and are then nailed with their upper edge to the respective nail plank. About the so laid track a covering web is performed and glued with a certain overlap in the area of its lower edge with the previously laid track in the region of the top edge. Subsequently, a second layer of roofing membranes can be applied in the same way to the already laid roofing membranes.

In addition to the effort to be operated and caused by the cutting to length of the roof sheets waste, the risk of rotting of the wood used for the nail planks is to be regarded as disadvantageous. Furthermore, caused by the nail planks unevenness in the roof and a reduction of the thermal barrier coating, which is also to be regarded as a disadvantage. The use of nails also carries the risk that the nails scattered and entered the roof skin. Finally, when attaching or pasting over the first layer with the second layer in the area of the nail heads, undesirable air entrapment may occur. Likewise, there may be moisture in the area of the nail heads. Finally, in the use state occurring movements of the roof - for example, due to surface stress caused by snow or due to changes in length as a result of temperature fluctuations (day / night or summer / winter) - repeatedly lead to "emigration". of nails from the nail planks. Such movement-related emigration is also known from wood screws in wooden structures.

OBJECT OF THE INVENTION

The object of the present invention is to avoid the above-mentioned disadvantages. In particular, a possibility for fixing roofing membranes, in particular bituminous membranes or polymer bitumen membranes, to thermal insulation elements of a roof structure without the use of nail planks should be created. With this mounting option further moisture ingress or air entrapment should be avoided. Finally, the possibility of attachment should also allow for use-related movements of the roof permanently stable attachment of roofing membranes.

PRESENTATION OF THE INVENTION

In order to dispense with the attachment of roofing membranes, in particular bituminous membranes or Polymerbitumenbahnen, on a non-nailable construction of a roof, especially on thermal insulation elements on the use of nail planks, a screw is provided according to the invention, which allows the bitumen membranes directly to the thermal insulation elements to be able to screw. It is assumed that the thermal insulation elements themselves are already attached to a corresponding substructure. The screw according to the invention has a screw shaft with a thread running around it and a screw head. The screw head is designed in large format, i. he has over conventional nails, which are commonly used for the nailing of bituminous sheets, for example on nail planks, a significantly larger area.

The screw head is tapered at its edge, so that a sticking, which takes place for example when applying a second layer of bitumen membranes, is made possible without air trapping. Concretely, the screw head has an outer surface that includes a curved outer surface portion and an inner surface that includes a curved inner surface portion. The curvature is carried out in each case in the direction of the screw shaft, so that a cross section of the screw parallel to a longitudinal axis of the screw shaft is reminiscent of a mushroom shape. Outer and inner surfaces are each bounded by a boundary edge in the radial direction to the outside. Accordingly, it is in a screw for fastening waterproofing membranes, especially of bitumen, not nagelbaren structures, in particular thermal insulation elements as part of a roof construction with a screw shank, a screw shaft extending thread and a screw head with an outer surface and an inner, pointing to the screw shank Surface provided according to the invention that the outer surface has a curved in the direction of the screw shaft outer surface portion and the inner surface has a curved in the direction of the screw shaft inner surface portion, wherein the outer surface is bounded by an outer boundary edge and the inner surface of an inner boundary edge, and that a tangent to the outer surface portion at a point of the outer boundary edge with a tangent to the inner surface portion at a point of bordering edge forms an acute angle. When the curved outer and inner surface portions each extend to the boundary edge, the tangents are applied to the curved outer and inner surface portions, respectively. However, it is also conceivable that the outer or inner surface connects with a flat portion of the outer or inner boundary edge. In this case, the tangents are placed on the corresponding flat piece of the outer or inner surface.

Due to the curvature and the pointed convergence of inner and outer surface at the edge of the screw head results in a shape that causes the screw when inserting with the outer and inner boundary edge penetrates into the surface of the roofing membrane or bitumen a piece. This results in a seal surrounding the screw head, which reliably prevents the penetration of moisture between the screw head and the roof membrane in the direction of the screw shank. In the event that no distance between the outer and inner boundary edge is provided, the outer and the inner boundary edge coincide and form a sealing edge, which can penetrate particularly easily into the surface of the roofing membranes. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that the distance between the outer 2/14 Austrian Patent Office AT13 303U1 2013-10-15

Boundary edge and inner boundary edge is zero and that outer and inner boundary edges form a sealing edge.

In the case of a larger distance is provided that the screw head between the outer and inner boundary edge forms a flat sealing strip. The distance is measured along a connecting line between the outer and inner sealing edge, wherein the connecting line lies in the plane of the sealing edge and is preferably normal to a screw shaft axis. The sealing strip is initially flat against the surface of the roofing membrane and ensures a reliable seal even with less penetration into the surface of the roofing membrane. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that the distance between the outer boundary edge and the inner boundary edge is greater than zero and that the screw head between the outer and inner boundary edge forms a flat sealing strip.

Particularly good, the sealing edge or sealing strip can then penetrate into the surface of the roof sheet when the acute angle is less than 30 °.

The seal can be optimized by a sealing lip is formed on the sealing edge or sealing strip or the screw head forms a sealing lip there. In order to facilitate penetration of the sealing lip in the surface of the roofing membranes, the sealing lip is not flat, but has a sealing lip tip facing in the direction of the screw shaft. The sealing lip tip is obtained by the meeting or as a section line rectilinear portions of the sealing lip or by a curvature of the sealing lip. In the latter case, the curvature is convex with respect to an end of the screw shaft opposite the screw head. The sealing lip tip is that point or portion of the sealing lip whose distance to the screw head opposite end of the screw shaft is the lowest, wherein the distance is measured parallel to the screw shaft and to the screw shaft axis. Therefore, it is provided in a particularly preferred embodiment of the screw according to the invention that a sealing lip with a pointing in the direction of the screw shaft sealing lip tip is arranged on the sealing edge or the sealing strip. This ensures that even the first layer of roofing membranes is so tight that, for example, rainfall occurring before the application of a second layer can not penetrate into the thermal insulation under the first layer. Accordingly, the sealing lip penetrates when screwing the screw into the surface of the bituminous sheet.

Thus, penetration of the sealing edge, the sealing strip or the sealing lip is easily possible in the surface of the roof sheet, it is provided in a preferred embodiment of the screw according to the invention that the inner surface has a depth which is at least 1.5 mm, wherein the depth in the axial direction of the screw shaft between the outer boundary edge, the inner boundary edge or the sealing lip tip and one of them with respect to the axial direction of the screw shaft farthest bottom portion of the inner surface is measured.

The sealing edge or sealing strip or sealing lip can then penetrate particularly far into the surface of the roofing membrane, if the inner surface of the screw head does not contact the surface of the roofing membrane as flat as possible. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that the inner surface consists entirely of the curved inner surface portion. In this case, the bottom portion consists only of a circle on the inner surface.

Sometimes too deep penetration of the sealing edge or sealing strip or sealing lip in the surface of the roofing membrane is not desirable. Therefore, it is provided in a particularly preferred embodiment of the screw according to the invention that the inner surface between the curved inner surface portion and the screw shaft has a flat and with respect to the axis of the screw shaft normally extending second portion. Furthermore, it is provided in a particularly preferred embodiment of the screw according to the invention that the second portion simultaneously forms the bottom portion. As soon as the second section or bottom section has been tightened at the 3/14 Austrian Patent Office AT13 303U1 2013-10-15

Surface of the roof membrane rests, a much higher torque must be spent for further screwing, whereby the user is induced to screw the screw not further.

In order to keep as small as possible, especially with regard to the application of a second layer of roofing membranes, bumps, the screw head is not continuously curved, but has a, preferably centrally located, flat head portion. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that the outer surface has a head portion which is flat and is aligned normal to the axis of the screw shaft.

To avoid "emigration" to prevent the screw during use-related movements of the roof, slats are provided, which are arranged on the inner surface and protrude in the direction of screw shaft or projecting. The slats penetrate when screwing the screw into the surface of the roofing membranes and thus secure the screw against unscrewing. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that are arranged on the inner surface in the direction screw shank projecting lamellae.

The lamellae can be arranged both on the curved inner surface portion and on the second portion or bottom portion. The arrangement on the second section or bottom section allows a particularly stable design of the slats. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that the lamellae are arranged on the curved inner surface portion and / or on the second portion.

In order to make the penetration of the lamellae into the surface of the roofing membranes during the turning of the screw particularly efficient, it is provided in a particularly preferred embodiment of the screw according to the invention that the lamellae run tangentially to the screw shank. This also allows a particularly stable protection against unscrewing the screws due to use-related roof movements.

Thus, the screw can be particularly easily screwed into the roofing membranes and the underlying thermal insulation elements, the screw shaft at the opposite end of the screw head on a tip. Accordingly, it is provided in a particularly preferred embodiment of the screw according to the invention that the screw shaft has a lateral surface which forms a lateral surface of a cone or a truncated cone in an end region of the screw shaft opposite the screw head.

In order to additionally support the slight screwing and to prevent the risk of tearing of the roofing sheet and / or the thermal insulation elements, it is provided in a particularly preferred embodiment of the screw according to the invention that the thread is designed self-tapping.

In order to favor the attachment of a screwdriver and to transmit a torque safely by means of the screwdriver, it is provided in a particularly preferred embodiment of the screw according to the invention that the screw head has a Phillips. That There are provided cross-shaped slots in the screw head for attaching the appropriate screwdriver.

In order to completely eliminate corrosion and minimize manufacturing costs, it is provided in a particularly preferred embodiment of the screw according to the invention that the screw is made of plastic. The lower strength compared to metal plays when screwing the screw in thermal insulation elements insofar no role, since the heat insulation elements are usually comparatively softer than wood and therefore do not have too large torques acting on the screw when screwing, which mechanically overload the screw and would damage , 4/14 Austrian Patent Office AT 13 303 U1 2013-10-15 BRIEF DESCRIPTION OF THE FIGURES [0023] The invention will now be explained in more detail by means of an exemplary embodiment. The drawings are exemplary and are intended to illustrate the inventive idea, but in no way restrict it or even reproduce it.

[0032] [0032] [0032] [0032]

Showing:

Fig. 1 is an axonometric view of a screw according to the invention with a view of an outer surface of a screw head

Fig. 2 is an axonometric view of the screw with respect to an inner surface of the screw head

Fig. 3 is a side view of the screw

Fig. 4 is a plan view of the screw with a view of the outer surface of the screw head

Fig. 5 is a plan view of the screw with a view of the inner surface of the screw head

6 is a sectional view taken along section line A-A in Fig. 4th

7 is an enlarged detail view of the area 21 in FIG. 6

Fig. 8 is a sectional view of a roof construction, in which use screws according to the invention

WAYS FOR CARRYING OUT THE INVENTION

Fig. 1 shows an axonometric view of a screw 1 according to the invention for direct attachment of roofing membranes 25, in particular bituminous membranes or polymer bitumen membranes, to thermal insulation elements 26 of a roof structure 27, cf. Fig. 8. The screw 1 has a screw shank 2, on which a thread 3 is arranged. The thread 3 is designed to be self-tapping in order to facilitate the penetration of the screw 1 into the surface of the roofing membranes 25 or the underlying thermal insulation elements 26, without tearing the roofing membranes 25 or thermal insulation elements 26 when the screw is screwed in. Further, the screw 1 comprises a screw head 4 having an outer surface 5 visible in FIG. 1. The outer surface 5 comprises a curved outer surface portion 5a and is bounded radially outward by an outer boundary edge 7, the outer boundary edge 7 being shown in FIG Embodiment directly to the curved outer surface portion 5a connects.

Furthermore, in the middle of the screw head 4, a flat head portion 12 can be seen, which is normally on a screw shaft axis 23 (see Fig. 3). In the area of the screw shaft axis 23, the screw 1 in the head section 12 has a cross slot 15 for attaching a suitable screwdriver.

The screw head 4 also has an inner surface 6, which faces the screw shaft 2 and can be seen in the axonometric view of FIG. The inner surface 6 comprises a curved inner surface portion 6a and is bounded radially outwardly by an inner boundary edge 28, the inner boundary edge 28 in the embodiment shown directly following the curved inner surface portion 6a, cf. Fig. 6. Also clearly visible in Fig. 2 are fins 24 which penetrate when screwing the screw 1 in the surface of the roofing membranes 25 and prevent the screw 1 is unscrewed by use-related movements of the roof.

Likewise, a sealing lip 20 can be seen, which is arranged on a sealing strip 31, which forms the screw head 4 between the outer 7 and inner boundary edge 28, see. Fig. 7. The sealing lip 20 forms a particularly good seal to prevent moisture 5 keitstritt between screw head 4 and roofing membrane 25th Austrian Patent Office AT13 303U1 2013-10-15.

Fig. 3 shows a side view of dimensions of an embodiment of the inventive screw 1. The screw head 4 has a diameter 16 of 40 mm, in the example shown, the sealing lip 20 forms the outermost edge of the screw head 4 seen in the radial direction. The screw 1 has an overall length 17 of 70 mm. The self-tapping thread has an outer diameter 19 of 20 mm and a thread 18 of 8 mm.

Fig. 4 shows a plan view of the screw head 4 with a view of the outer surface 5, wherein the cross recess 15 is particularly well recognizable. Fig. 5 shows as a counterpart to a plan view of the inner surface 6, wherein the arrangement of the fins 24 is tangential to the screw shaft 2 is particularly well recognizable. The tangential arrangement of the lamellae 24 on the one hand facilitates the penetration of the lamellae 24 into the surface of the roofing membranes 25 when the screw is screwed in. On the other hand, this arrangement provides effective protection against "emigration". the screw due to use-related movements of the roof.

Fig. 6 shows a sectional view of the screw 1 according to the section line A-A in Fig. 4, wherein the arrows in Fig. 4 indicate the viewing direction. In this view, on the one hand, a tip of the screw shank 2 in the end region 13, which lies opposite the screw head 4, recognizable. This tip is formed by a conical lateral surface 14 of the screw shaft in the end region 13 and facilitates the penetration of the screw 1 into the surface of the roofing membranes 25 or the underlying thermal insulation elements 26, without the roofing membranes 25 or thermal insulation elements 26 tearing when screwing in the screw.

Furthermore, in Fig. 6, the curved outer surface portion 5a and the curved inner surface portion 6a are clearly visible. A tangent 29 to the curved outer surface portion 5a at a point of the outer boundary edge 7 includes a tangent 30 to the curved inner surface portion 6a at a point of the inner boundary edge 28 at an acute angle 8, which is typically less than 30 °. This facilitates the penetration of the formed between the outer 7 and inner boundary edge 28 sealing strip 31 in the surface of the roofing sheets 25, if no sealing lip 20 is provided, see. Fig. 7, which illustrates a region 21 comprising the outer boundary edge 7 enlarged. In the illustrated embodiment, a sealing lip 20 is integrally formed on the sealing strip 31. So that these can easily penetrate into the surface of the roofing membranes 25, the sealing lip 20 is convexly curved with respect to the end region 13 and has a tip 22.

Finally, it can be seen in FIG. 6 that the inner surface 6 forms a bottom section 9 which, with respect to the sealing lip tip 22, has a depth 10 of 1.5 mm. This depth 10 is the maximum distance of the inner surface 6 to the sealing lip tip 22, measured in the direction of the screw shaft axis 23. The bottom portion 9 is executed in the embodiment shown as a flat second portion 11 of the inner surface 6, which is normal to the screw shaft axis 23. The fins 24 are preferably integrally formed in this second section 11 to the inner surface 6, which guarantees a particularly stable design of the fins 24. 6/14 Austrian Patent Office AT13 303U1 2013-10-15

REFERENCE LIST 1 Screw 2 Screw Shank 3 Thread 4 Screw Head 5 Outer surface of screw head 5a Curved outer surface portion 6 Inner surface of screw head 6a Curved inner surface portion 7 Outer boundary edge 8 Sharp angle 9 Bottom portion 10 Depth 11 Second portion of inner surface 12 Head portion of outer surface 13 End portion of screw shaft 14 Shell surface of screw shaft 15 Phillips 16 Screw head diameter 17 Total screw length 18 Thread 19 Outer diameter 20 Sealing lip 21 Area including outer boundary edge 22 Sealing lip tip 23 Screw shank axis 24 Slat 25 Roofing sheet 26 Thermal insulation element 27 Roof construction 28 Inner boundary edge 29 Tangent to outer surface section 30 Tangent to inner surface Surface section 31 Sealing strip 7/14

Claims (17)

Austrian Patent Office AT13 303U1 2013-10-15 Claims 1. Screw (1) for fastening waterproofing membranes (25), in particular of bitumen, on non-nailable constructions, in particular thermal insulation elements (26), as a component of a roof construction (27) with a screw shank (27). 2), a screw thread (2) extending thread (3) and a screw head (4) having an outer surface (5) and an inner, the screw shaft (2) facing surface (6), characterized in that the outer surface ( 5) has a curved in the direction of the screw shaft (2) outer surface portion (5a) and the inner surface (6) in the direction of the screw shaft (2) curved inner surface portion (6a), wherein the outer surface (5) from an outer boundary edge (7) is limited and the inner surface (6) of an inner boundary edge (28), and that a tangent (29) to the outer (5) Oberflächenabsch at an acute angle (8) at a point of the outer boundary edge (7) with a tangent (30) to the inner surface portion (6) at a point of the inner boundary edge (28). 2. Screw (1) according to claim 1, characterized in that the acute angle (8) is less than 30 °. 3. Screw (1) according to one of claims 1 to 2, characterized in that the distance between the outer boundary edge (7) and inner boundary edge (28) is equal to zero and that outer (7) and inner boundary edge (28) form a sealing edge , 4. Screw according to one of claims 1 to 2, characterized in that the distance between the outer boundary edge (7) and inner boundary edge (28) is greater than zero and that the screw head (4) between the outer (7) and inner boundary edge (28). a flat sealing strip (31) is formed. 5. Screw (1) according to one of claims 3 to 4, characterized in that on the sealing edge or the sealing strip (31) a sealing lip (20) with a in the direction of the screw shank (2) facing sealing lip tip (22) is arranged. 6. screw (1) according to any one of claims 1 or 5, characterized in that the inner surface (6) has a depth (10) which is at least 1.5 mm, wherein the depth (10) in the axial direction of the screw shaft ( 2) between the outer boundary edge (7), the inner boundary edge (28) or the sealing lip tip (22) and one of which with respect to the axial direction of the screw shaft (2) farthest bottom portion (9) of the inner surface (6) is measured , 7. screw (1) according to any one of claims 1 to 6, characterized in that the inner surface (6) entirely from the curved inner surface portion (6a) consists. A screw (1) according to any one of claims 1 to 6, characterized in that the inner surface (6) between the curved inner surface portion (6a) and the screw shank (2) is plane and in relation to the axis (23) of the Screw shaft (2) normally extending second portion (11). 9. screw (1) according to claim 8, characterized in that the second portion (11) simultaneously forms the bottom portion (9). 10. screw (1) according to one of claims 1 to 9, characterized in that the outer surface (5) has a head portion (12) which is flat and is aligned normal to the axis (23) of the screw shaft (2). 11. Screw (1) according to one of claims 1 to 10, characterized in that on the inner surface (6) in the direction of the screw shaft (2) projecting lamellae (24) are arranged. 8/14 Austrian Patent Office AT 13 303 U1 2013-10-15 12. Screw (1) according to claim 11, characterized in that the lamellae (24) are arranged on the curved inner surface portion (6a) and / or on the second portion (11). 13. Screw (1) according to one of claims 11 to 12, characterized in that the lamellae (24) extend tangentially to the screw shank (2). 14. Screw (1) according to one of claims 1 to 13, characterized in that the screw shank (2) has a lateral surface (14) which in a screw head opposite end portion (13) of the screw shaft (2) has a lateral surface of a cone or a truncated cone forms. 15. Screw (1) according to one of claims 1 to 14, characterized in that the thread (3) is self-tapping. 16. Screw (1) according to one of claims 1 to 15, characterized in that the screw head (4) has a cross slot (15). 17. Screw (1) according to one of claims 1 to 16, characterized in that the screw (1) consists of plastic. For this 5 sheets drawings 9/14