EP2646697A2

EP2646697A2 - Self-locking nut

Info

Publication number: EP2646697A2
Application number: EP11833605.6A
Authority: EP
Inventors: Frank-Uwe Diener; Wolfgang Giraud; Siegfried OBERNDÖRFER; Thorsten Schraer
Original assignee: Ruia Global Fasteners AG
Current assignee: Ruia Global Fasteners AG
Priority date: 2010-11-29
Filing date: 2011-11-24
Publication date: 2013-10-09
Also published as: US20130236265A1; DE202010015819U1; CN103348147A; CA2819179A1; WO2012076004A2; AU2011341143A1; BR112013011974A2; KR20130140751A; WO2012076004A3; JP2013543963A; MX2013005993A

Abstract

The invention relates to a self-locking nut (10) having an internal thread (12) with a core hole which has one or a plurality of regions (14) having a reduced internal diameter.

Description

Self-assured mother

Technisches GebietTechnical area

The present invention relates to a self-locking nut, which is also referred to as a "clamping nut", with a core hole and thread grooves.

Stand der TechnikState of the art

Such self-locking nuts according to the prior art have various disadvantages. So-called "pinch nuts" in which the thread, the hexagonal outer shape or a small cone are squeezed at the tip at two or more points, have the disadvantage that they require an additional manufacturing step and that the clamping in only two pinched points not is sufficient.
Another prior art solution is the so-called three-cone clamping nut, which has three cones at the tip, which are bent inwardly to produce the clamping action or increased loosening torque. All these self-locking nuts in the prior art generally tend to eat, that is, they can not screw properly or can not be solved after the single tightening or at least not non-destructive.
Another alternative from the prior art are the so-called "polystop" nuts. These have a plastic ring at the top, which produces the clamping action. The use of an additional component, in addition to a different material, makes this solution very expensive. In addition, most of these prior art self-locking clamping nuts suffer from the disadvantage that they have a greater height than standard nuts and therefore require more space in the application as well as longer screws or bolts, thereby incurring additional costs.
In summary, all existing clamping nuts or self-locking nuts are a compromise between ideal self-assurance, minimal seizure, minimum height, and low manufacturing costs. All such nuts in the prior art are a more or less good compromise of these tasks. None of the aforementioned self-locking nuts from the prior art solve all four tasks optimally.

Darstellung der ErfindungPresentation of the invention

It is therefore an object of the present invention to provide such a self-locking nut or locknut, which is finished without additional effort, has no additional space and weight requirements, does not seize and still has a good clamping effect.
According to the invention, this object is achieved by a self-locking nut or clamping nut which has a core hole with a reduced inside diameter in one or more areas.
Alternatively, the areas between the thread grooves in one or more parts of the internal thread can not be flattened, but can be formed in a pointed ridge which protrudes beyond the remaining internal thread.
Such a clamping nut according to the invention has the following advantages: The manufacturing costs are lower and can correspond to the production costs of a standard nut without clamping or self-locking effect, since no additional material and no additional processing step is necessary to achieve the clamping effect.
The clamping effect can be co-produced according to the invention during cold working or during thread cutting.
Nuts according to the invention weigh less and have a lower overall height than tapered clamping nuts. As a result, they do not require so long screws or bolts and no extra space in the application.
The clamping nuts according to the invention also have a much better clamping action, since the clamping does not act diagonally, and finally the self-locking nuts according to the invention have little or no tendency to seizure.
According to the invention, it is particularly preferred to provide three areas with reduced inner core diameter, which are equally spaced from each other over the circumference of the core hole. In this way, an optimal uniform clamping effect can be achieved.
Preferably, it suffices if the areas of reduced core hole inner diameter each extend over only a small portion of the circumference of the core hole of preferably 10 to 15 degrees. In this way, a seizure of the screw connection is prevented, although still a sufficiently high clamping effect can be achieved.
Further, it is preferred to attach the areas with reduced core hole diameter only in the three to four last, that is remote from the screw side of the nut threads of the internal thread. The nut then only clamps when it is screwed almost completely onto the screw or the bolt.
The areas of reduced core hole diameter may preferably be formed by flat portions on the inner diameter of the core hole. In this way, the nut according to the invention is particularly easy to produce, since the core hole is usually produced today by pressing and only at the remote from the workpiece end of the nut a ram with corresponding flats must be used. Apart from the one-time conversion of the tool, so the stamp, then incurred no further costs in the production of the mother of the invention.
A better clamping effect, albeit with a somewhat more complicated production of the tool, results when the areas with reduced core hole diameter are formed by slightly inwardly curved portions on the circumference of the core hole.
In order to further reduce the tendency of the jam nut to seizure, it is preferable to form the transition from the normal core hole periphery to the reduced inner diameter regions by small radii.
In the alternative embodiment of the invention, it is preferable to provide three sharply ridge formed portions equally spaced around the circumference of the internal thread. In this way, a uniform clamping action when screwing is ensured.
Preferably, the areas formed as a sharp ridge extend only over a small portion of the circumference of the internal thread, since this can further reduce the tendency to seizure.
Further, it is preferable if the formed as a sharp ridge areas extend only between the three to four last, that is remote from the workpiece side of the nut thread furrows of the internal thread. In this way, the mother only clamps when it has been screwed sufficiently far on the bolt.
A particularly favorable production results when the formed as a sharp ridge areas are made by the fact that the adjacent thread grooves are formed at chipless production of the thread deeper and / or wider. In this way, more material is thrown up, which can then form the sharp burr.

Kurze Beschreibung der ZeichnungenBrief description of the drawings

The present invention will be explained in more detail below with reference to the embodiment shown in the drawings. It shows:
Figure 1 is a sectional view of a clamping nut according to the invention;
FIG. 2 shows the clamping nut of FIG. 1 from above;
3 shows the clamping nut of Figure 1 from the side and along the line AA
the figure 4 cut with detailed representation of the internal thread;
Figure 4 shows the clamping nut of Figure 1 from above with screwed and cut at height of the nut nut;
FIG. 5 shows the illustration of FIG. 3 with the bolt inserted;
FIG. 6 shows the detail X of FIG. 5.

Bester Weg zur Ausführung der ErfindungBest way to carry out the invention

Figure 1 shows a clamping nut according to the invention or self-locking nut 10 from the side in a sectional view. The internal thread 12 is not shown in greater detail in accordance with the usual drawing standards. Shown are those areas 14 in which the core hole diameter is reduced, or increased burrs are provided between the thread grooves. As shown, these areas 14 extend over almost half the length of the internal thread of the nut 10, these are usually three to four threads.
Figure 2 shows the mother of Figure 1 from above, again the internal thread 12 and the areas 14 can be seen with reduced core hole diameter or raised burrs between the thread grooves. In FIG. 2 it can be seen very clearly that in the present embodiment there are three areas 14 with reduced core hole diameters or raised burrs between the thread grooves, which are distributed equally spaced over the thread turn, so that the distance between the individual areas 14 is 120 degrees.
It is also very clearly visible that the areas 14 each relate only to a very short arc section of the thread of about 10 to 15 degrees.
FIG. 3 shows the nut of FIG. 1 partially cut along the line A-A of FIG. 4 with a detailed representation of the internal thread 12. In FIG. 3, the area 14 on the top right in the image can already be seen very well with the differently shaped thread according to the invention , In the lower part of the illustrated nut 10, ie on the side of the nut with which the nut is screwed onto a bolt or from a screw is screwed into the nut, a conventional internal thread 12 is shown. This consists, as usual, of V-shaped grooves 16 between which flattened portions 18 extend, which abut geo-metrically on the lateral surface of a cylinder with the core hole diameter.
In the area 14, on the other hand, the flanks 19 of the V-shaped grooves 16 are extended and meet in a pointed ridge 20, which therefore projects into an imaginary cylinder with the core hole diameter.
Figure 4 shows the clamping nut according to the invention or self-locking nut 10, in which case a bolt 100 is screwed, which is shown cut at the height of the upper end of the nut 10. Again, the areas 14 with the reduced core hole diameter are clearly visible again. Here is also very well recognizable, as in the area 14, the core hole diameter of bolt 100 and nut 10 coincide, whereby the present invention desired clamping effect is brought about.
FIG. 5 likewise shows the combination of nut 10 and bolt 100 shown in FIG. 4, wherein the nut 10 is again shown partially cut along the lines A-A of FIG. 4 as in FIG. The bolt 100 is not shown cut for clarity, so you can see the external thread 102 of the bolt well. The bolt 100 may be commercially available and comply with the usual technical standards. The inventive meshing of the external thread 102 of the commercial bolt 100 with the inventively modified region 14 of the internal thread 12 of the nut 10 is shown in more detail than detail X in Figure 6. Here, the internal thread 102 of the bolt 100 is shown cut to better illustrate the clamping action of the invention. In the lower region of the detail X, the region of the internal thread 12 of the nut 10 is shown, which is normal, that is formed according to the prior art, so that the difference to the inventive design of regions 14 of the internal thread 12 emerges even more clearly.
Namely, the lower two threads of the internal thread 12 of the nut 10 in Fig. 6 are normally formed according to the prior art, while the upper three threads shown in Fig. 6 have a reduced core hole diameter. As can be seen very clearly in FIG. 6, the flanks 19 of the V-shaped thread grooves 16 normally terminate in a flattened region 18 which separates the individual thread grooves 16 and whose surface corresponds to the surface area of a cylinder having the standard core hole diameter. In this way, over the entire length of thread required for low-friction screwing of the bolt 100 in the nut 10 game 22 is guaranteed. Only when a biasing force between bolt 100 and nut 10 acts normally flanks 19 of the nut thread against the opposite flanks of the bolt are pressed in not self-locking nuts, and by the thereby triggered friction holds the screw.
In the upper region of the detail X, that is to say in the upper three threads shown, the plateau-like region 18 is missing between the individual threads 16 of the internal thread 12 of the nut 10. Instead, the flanks 19 of the individual thread grooves 16 in this region 14 pass over only a very large part small radius into each other, whereby protruding ridges 20 are formed between the thread grooves 16.
These burrs 20, as shown very nicely in FIG. 6, forcibly come into engagement with the valley bottom of the thread grooves 116 of the external thread 102 of the bolt 100 due to the geometric conditions. FIG. 6 shows the theoretical geometric relationships. Of course, the black area of the ridges 20 shown is actually not present, but in this area the ridges 20 are elastically deformed by the contact pressure to the valley bottom of the grooves 116 of the bolt 100. Thus, the burrs 20 are actually somewhat "flattened" while penetrating into the bottom of the grooves 116 of the external thread of the bolt 100 at the same time. Since this effect occurs from several sides simultaneously, a clamping of the screw and thus a self-assurance is achieved, regardless of whether a biasing force has already occurred during screwing, or not. In order to achieve the most symmetrical clamping force and to avoid tipping the nut, two or more, preferably three uniformly spaced regions 14 are provided according to the invention over the circumference of the internal thread 12 of the nut 10.
According to the invention, the regions 14 can be manufactured in different ways:
On the one hand, nuts are usually manufactured today by cold forming, stamping punches with the core hole diameter from above and below, and then cutting, rolling or rolling the thread. When rolling or rolling, if appropriate, the punch diameter can be selected to be somewhat smaller, since with a chipless production of the internal thread 12 of the nut 10, the material displaced by the formation of the thread grooves 16 is displaced into the regions 18 between the thread grooves.
According to the invention, the regions 14 can now be produced simply by grinding or hollowing out these regions on the stamp which acts on the mother from above. In this way, either a secant-shaped, ie flat region 14 can be produced, or what is still preferred according to the invention and also shown here, an inwardly curved region 14. This inward curvature is particularly preferred in order to seize the thread in the clamping state avoid.
Preferably, the curvature is defined with a large radius from the outside.
Alternatively, the regions 14 can be produced in non-cutting production of the internal thread 12 by making the thread grooves 16 of the internal thread 12 deeper and / or wider in the region 14, whereby more material is deformed and correspondingly higher burrs are raised between the individual threads become.
In both cases, the production of a clamping nut according to the invention is not complicated or complicated than the production of a commercial-usual mother without clamping action. Only the manufacturing tools, so either the punch for the production of the core hole or the tools for thread rolling or thread rolling, must be performed once differently.

Claims

Self-locking nut (10) having an internal thread (12) with a core hole, characterized in that the core hole of the nut (10) has one or more areas (14) with a reduced inner diameter.
Self-locking nut (10) according to claim 1, characterized in that the areas (14) are provided with reduced internal core diameter, which are equally spaced from each other over the circumference of the core hole.
A self-locking nut (10) according to claim 1 or 2, characterized in that the reduced core-hole inner diameter regions (14) each extend over a small portion of the circumference of the core hole of preferably 10 to 15 °.
Self-locking nut (10) according to claim 1, 2 or 3, characterized in that the areas (14) with reduced core hole diameter only over the three to four last, that is remote from the Einschraubseite the nut (10) threads of the internal thread (12 ).
A self-locking nut (10) according to any one of claims 1 to 4, characterized in that the areas (14) of reduced core hole diameter are formed by flat portions on the inner diameter of the core hole.
Self-locking nut (10) according to one of claims 1 to 4, characterized in that the areas (14) with reduced core hole diameter are formed by slightly inwardly curved portions on the inner diameter of the core hole.
A self-locking nut (10) according to any one of claims 1 to 6, characterized in that the transition from the normal core hole circumference to the reduced inner diameter portions (14) is formed by small radii.
Self-locking nut (10) having an internal thread (12) with thread grooves (16), characterized in that the areas (18) between the thread grooves (16) in one or more parts (14) of the internal thread (12) not flattened, but in a pointed ridge (20) are formed, which projects beyond the remaining internal thread (12) inwardly.
Self-locking nut (10) according to claim 8, characterized in that three areas formed as a sharp ridge (20) over the circumference of the internal thread (12) are provided equally spaced.
Self-locking nut (10) according to claim 8 or 9, characterized in that the sharp ridge (20) formed areas each extend only over a small portion (14) of the circumference of the internal thread (12).
Self-locking nut (10) according to claim 8, 9 or 10, characterized in that formed as a sharp ridge (20) areas only between the three to four last, that is remote from the workpiece side of the nut (10) thread furrows (16) of the internal thread (12) extend.
Self-locking nut (10) according to any one of claims 8 to 11, characterized in that the pointed ridge (20) formed areas are made by the fact that the adjacent thread grooves (16) with non-cutting production of the thread (12) deeper and / or wider be formed.