Patent Application
20160327081
The invention relates to a screw comprising a screw head that is provided with an engagement point, a shaft that defines a screw axis and has a thread, and a thread-free shaft portion that is arranged between the thread and the screw head.
The invention further relates to a fastening arrangement and to a use of a screw according to the invention.
The present screws, fastening arrangements and uses are mainly for fastening outer or inner metal sheets of sandwich panels. The sheet stacks used in this case are intended to be securely held together by screws which are, in turn, cost-effective and can be inserted simply and quickly during use.
Fastening arrangements of the stated type are associated in particular with two problems. Firstly, a screw that has been screwed into the sheet stack should be prevented from being able to be removed again from the sheet stack by means of unintentional loosening. Secondly, it is desirable to ensure that the fit of the screw in the sheet stack is as free as possible from backlash.
A fundamental requirement for the resistance to loosening is the mentioned thread-free shaft portion between the thread and the screw head, it still being entirely permissible, however, for contact between the final thread turn and the sheet stack to remain or to occur precisely in order to provide the mentioned zero backlash or as little backlash as possible of the screw in the fastening arrangement.
The object of the invention is therefore to specify a screw and thus a fastening arrangement and a use of the screw, in which the screw is resistant to loosening and is a component of the fastening arrangement that is as free as possible from backlash. It should be possible for large tightening forces to be generated and large shearing forces to be absorbed.
This object is achieved by the independent claims. Advantageous embodiments of the invention are set out in the dependent claims.
The invention further develops the generic screw in that a head end of the thread is cut off. The thread thus does not end in the manner of a conventional thread on the side of the screw head. Conventional threads gradually peter out, usually as a result of the thread production by cold forming methods, in particular thread rolling. This means that the material protruding through the thread above the shaft gradually reduces as it nears the screw head, until a thread is no longer discernible. The thread “peters out to zero”. This is different in the screw according to the invention. In this case, the head end of the thread is cut off, i.e. said thread ends abruptly and not gradually. There is thus still a significant amount of thread material immediately beside the transition between the thread-free shaft and the thread end. The thread does not peter out to zero, but rather ends abruptly and suddenly. The resistance of the screw to loosening is thereby improved. If the thread-free shaft portion has passed through the screw hole, the cut-off end of the thread makes loosening difficult. In a conventional screw, in which the thread gradually peters out to zero, loosening of the screw is promoted, since there is virtually no resistance to be overcome at the start of the engagement between the thread and the adjacent layer of the fastening arrangement, and there are no specific positions that would prevent the thread from re-engaging in the layers of the fastening arrangement. Minimal force in the return direction and loosening of the screw are sufficient to remove the screw again from the fastening arrangement, since the head thread end of said screw easily engages in the layers of the fastening arrangement. This is different in the screw according to the invention. In this case, the head end of the thread is cut off, with the result that it is far less likely, when the screw is withdrawn and loosened, that the thread end will engage in the stack of the fastening arrangement. Vibrations or other external influences will definitely not result in loss of the screw having the cut-off thread, but this can certainly occur in conventional screws and the “asymptotic” manner in which the thread peters out.
Rather more specially, the invention is particularly advantageously developed in that, remote from the thread-free shaft portion, the thread has a defined thread depth, and in that the head end of the thread forms a shoulder to the shaft that has a maximum radial height at a starting point that is greater than 10% of the thread depth, preferably greater than 20% of the thread depth, preferably greater than 40% of the thread depth, preferably greater than 60% of the thread depth, preferably greater than 80% of the thread depth, and preferably 100% of the thread depth. Simply a thread shoulder to the shaft having a small radial height of approximately 10% can be sufficient for significantly improving the resistance of the screw to loosening. Depending on the type of fastening arrangement in which the screw is used, larger or smaller radial heights in the region of the shoulder may be useful or necessary. In an extreme case, the thread may be cut off at its full height. In this case, the shoulder has a maximum radial height that is 100% of the thread depth of the screw remote from the thread-free shaft portion, i.e. in the “normal region” of the thread.
It can be advantageous for the shoulder to be defined by a radial cut having an axial cutting plane. The cutting plane thus produced is therefore perpendicular on the shaft and is parallel to the screw axis. Accordingly, there is no petering-out region of the thread proceeding from the shoulder towards the screw head, which region would have a circumferential component that could, rather, promote engagement of the thread in the stack of the fastening arrangement.
It can, however, also be provided for the thread, proceeding from the starting point of the shoulder, to end in at least one non-radial end face that tapers towards the shaft. It is thus not necessary to cut off the head end of the thread in a sharp and radial manner. Rather, it is also within the scope of the invention for the thread to end having a non-radial end face that is likewise designed such that there is a larger force for screwing the screw into the fastening arrangement upon loosening and/or less likelihood thereof than in a conventional screw having a thread that peters out in an asymptotic manner.
The invention further develops the generic prior art in that the thread ends adjacently to the thread-free shaft portion in an end plane that surrounds the shaft at least in part at a constant spacing from the screw head and forms an angle αE with the screw axis, in that, remote from the thread-free shaft portion, a head flank of the thread forms an angle αF with the screw axis, and in that the angle αE is smaller than the angle αF. An end plane of this kind comes into contact with the adjacent layer of the fastening arrangement at a plurality of points on the circumference of the screw, either when there is sufficient tension in the finished state of the fastening arrangement, or when the screw is withdrawn for any reason. In each case, the “flattened” end plane improves the contact between the thread and the rest of the fastening arrangement, with the result that the backlash of the screw in the fastening arrangement is reduced.
In this context, it can be particularly preferable for the end plane to extend radially.
According to another embodiment of the invention, it is provided for the thread to have a constant pitch when tapering towards the screw head across a plurality of thread turns, and to end at a pitch of 0 after a kink. The relationships between the angles αE and αF result almost automatically from the “kinking” of the thread from a true thread pitch to a thread pitch of 0. The threaded part having a thread pitch of 0 can then again be formed advantageously having a cut-off head end.
The screw according to the invention is particularly advantageously developed in that the thread-free shaft portion has, at least in part, a diameter that is greater than the core diameter of the thread and smaller than the outer diameter of the thread. Since at least the outermost layer of the layer stack in which the screw is inserted is generally pre-drilled such that the screw, together with the thread thereof, can be guided through the hole without contact, the hole has a significantly greater diameter than the core of the thread. Since the thread-free shaft portion is now selected having, at least in part, a greater diameter than the core of the thread, the backlash in the hole of the outer layer is reduced.
It can also be provided for the thread-free shaft portion to have, at least in part, a diameter that is smaller than or equal to the core diameter of the thread. As a result, the thread-free shaft portion penetrates the layer arrangement in a frictionless manner.
It can be provided for the thread-free shaft portion to comprise a step, adjacent to the screw head, having a shaft diameter that is greater than the core diameter of the thread.
According to a particular embodiment of the present invention, the screw is designed such that the screw is a drilling screw having a shaft that peters out into a boring tip. If the screw is formed as a drilling screw, the layer stack can optionally be provided with pre-drilled holes in one or more layers, or even without any pre-drilled holes.
It is also possible for the screw to be a drive-out screw having a thread that extends into the tip of the drive-out screw. A drive-out screw removes essentially no material, but rather displaces the material of layers that have not been pre-drilled or have been insufficiently pre-drilled, such that funnel-like structures form when the screw is screwed in. For example, if the lowest layer of a layer arrangement has not been pre-drilled, the funnel-like structure thus forms in this lowest layer. If the length of the thread-free shaft portion, the thickness of the stack and the thickness of the screw are well matched to one another, the funnel-like structure rests, in the finished state, with the edge thereof on the final thread, i.e. in particular on the end plane of the thread, loosening of the screw nonetheless being impossible or unlikely due to, in particular, of the cut-off end of the thread.
According to a preferred embodiment, it is provided for the thread to be a tapping-screw thread.
The screw can also be selected such that the thread is a single-start or multi-start thread.
The invention further consists in a fastening arrangement comprising a layer stack having at least one thin metal sheet and a screw according to the invention, wherein the thickness of the layer stack corresponds to the maximum length of the thread-free shaft portion. In this case, the focus should in particular be the thickness of the layer stack in the end state and in the immediate vicinity of the screw, since this thickness changes when the screw is screwed in, in particular if said screw is a drive-out screw.
It is preferred for the thin metal sheet to be the layer of the layer stack that is furthest from the screw head. This thin metal sheet is suitable in particular for shaping a funnel edge by the drive-out screw being screwed in, and thus for resting the funnel edge on the thread end in an advantageous manner.
A particular advantage is that the layer that is furthest from the screw head has a maximum thickness of 1 mm. In particular the thickness of the layer that is furthest from the screw head has a significant influence on the displacement mechanism described, as a result of which specific layer thicknesses have particularly advantageous effects, in particular thicknesses of less than 1 mm or even of 0.7 mm or even of less than 0.5 mm. The method is suitable, on this basis, for attaching profiles and other superstructures that require high tightening values to facades having very thin outer layers.
Thus, the invention also consists in a use of a screw according to the invention externally or internally on a building.
In particular, the use is designed for fastening outer or inner metal sheets of sandwich panels.
The invention will now be explained on the basis of particularly preferred embodiments, with reference to the accompanying drawings in which:
In the following description of the figures, like reference numerals denote like or similar components.
The head end 22 of the thread 18 has a particular design. Unlike in conventional screws, said end does not gradually peter out in the shaft 20 in an almost asymptotic manner or “to zero”, but instead is cut off. In this sense, the head end 22 of the thread 18 has a shoulder 24, wherein the thread, proceeding from a starting point 26 of the shoulder 24, tapers in a surface 30 towards the shaft 16. In the present case, the surface 30 has a curvature. Due to the particular design of the head end 22 of the thread 18, the screw 10 is provided with particular resistance to loosening, since a radial height of the thread that exists virtually to the end of the thread makes it more difficult for the thread to engage in the other components of the fastening arrangement when the screw 10 is withdrawn and loosened.
A further particular feature of the screw 10 can be identified in the angles αE and αF that the end plane 32 of the thread 18 and the normal flanks 34 of the thread 18 respectively form with the screw axis. In this case, the end plane of the thread 32 encloses a smaller angle αE with the screw axis than the flank 34 does in its angle αF. This ensures better contact of the screw 10 with other components of the fastening arrangement, as a result of which the backlash of the screw 10 in the fastening arrangement is reduced and which also makes a positive contribution to improved resistance to loosening. In the embodiment of
In this case, the head end 22 of the thread is defined by a radial cut having an axial cutting plane 28. This provides the main advantages in terms of resistance to loosening.
In this case, the end plane 32 of the thread encloses a right angle with the screw axis. In any case, here, too, the angle αE that the end plane 32 encloses with the screw axis is greater than the angle αF that an otherwise arbitrary flank 34 of the thread 18 forms with the screw axis.
In this case, the head end 22 of the thread 18 ends, proceeding from a starting point 26, in a plane, i.e. a surface without a curvature, that tapers towards the shaft 16.
In contrast to the screws according to
The head end 22 of the thread is again cut off, in a manner comparable to
The same applies to the end plane 32 of the thread 18 as has been set out above relating to
Up to now, screws have been described of which the threads have symmetrical thread flanks remote from the thread-free region. However, the invention can also be achieved using screws that have asymmetrical thread flanks
The features of the invention disclosed in the above description, the drawings and in the claims can be essential to the implementation of the invention both individually and in any combination.
| Number | Date | Country | Kind |
|---|---|---|---|
| 10 2014 000 940.8 | Jan 2014 | DE | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2015/050845 | 1/19/2015 | WO | 00 |
