EP1597741A1

EP1597741A1 - Switching shaft for a rotary switch

Info

Publication number: EP1597741A1
Application number: EP04713891A
Authority: EP
Inventors: Günther Reimold; Siegfried Mannuss
Original assignee: EGO Elektro Geratebau GmbH
Current assignee: EGO Elektro Geratebau GmbH
Priority date: 2003-02-24
Filing date: 2004-02-24
Publication date: 2005-11-23
Anticipated expiration: 2024-02-24
Also published as: DE502004003838D1; EP1597741B1; DE10308449A1; PL376928A1; PL205107B1; CN1754239A; ES2286609T3; WO2004075225A1; ATE362643T1; CN100435256C

Abstract

According to one embodiment of the invention, a switching shaft (11) comprising molded-on cams (17) or cam disks (15) can be created for a rotary switch. A reinforcement rib (25) which extends close to the ends of the switching shaft is provided on the outside of the switching shaft (11). Said reinforcement rib (25) is able to absorb tensile stress caused especially in the central area of the switching shaft (11) by pressure generated by switching contacts (19), allowing bending of the switching shaft (11) to be prevented.

Description

Description Switching shaft for rotary switches

Field of application and state of the art

The invention relates to a control shaft for rotary switches according to the preamble of claim 1. The control shaft can have molded cams or cam disks and trigger switch contacts of the rotary switch.

From EP 1 239 504 A1, a multi-layer shift shaft is known which has a core with a flattened D profile which can be inserted therein. This results in rib-like formations at one end, which can be used to trigger switching functions.

Task and solution

The object of the invention is to improve a shift shaft mentioned at the outset, in particular to improve the stability with an optimized use of material and production outlay. This object is achieved by a selector shaft with the features of claim 1. Advantageous and preferred embodiments of the invention are the subject of the further claims and are explained in more detail below. The wording of the claims is made the content of the description by express reference.

According to the invention, a shift shaft mentioned at the beginning has a rib-shaped or rib-like reinforcement on its outside. This runs in the axial direction and can absorb compressive stresses and above all tensile stresses in order to avoid bending of the selector shaft. On the one hand, it is possible to use several such Train reinforcements side by side in the same direction. With suitable dimensions, however, a single reinforcement rib is sufficient in many cases. A one-piece molding of the reinforcement is particularly advantageous here. This can further increase the strength.

The amplification can advantageously extend over a wide central region of the selector shaft, for example up to shortly before the respective end of the selector shaft. For example, it can take up 70% to 90% of the length of the selector shaft.

The selector shaft advantageously has a substantially constant cross section, if one disregards the cams or cam disks. This cross-section is only expanded in the area of the reinforcement by the additional cross-section of the reinforcement.

The reinforcement in the form of ribs should preferably be continuous and in one piece without any interruptions. On the one hand, it is possible to design the reinforcing rib with a constant thickness or cross-section. On the other hand, in certain areas in which local tensile stresses occur to an increased extent, a second reinforcing rib or a reinforcing rib with a larger cross section can be formed. It has proven to be advantageous if the gain projects from the selector shaft to an extent that is approximately 10% to 30%, in particular approximately 20%.

The reinforcement advantageously runs on a longitudinal region, which lies opposite a region which is particularly stressed by the cams or cam disks. This means that the reinforcement, in order to be able to absorb the tensile stresses, should point in the direction of force in which the strongest forces are exerted on the cams or cam disks in a certain rotational position. These powers stir from switching contacts or the like, which are actuated or moved by the cams. In many cases, switch contacts are moved in certain different rotational positions. However, there is usually a particularly concentrated or medium range in which the aforementioned strongest forces can be determined.

The selector shaft can be manufactured in such a way that it consists of plastic in an outer area or has an outer plastic layer. It is thus possible for the selector shaft to have a core which, for example, either consists of a different and more stable material or is of a constant cross section and is therefore of a simpler design. Switching shaft and / or core can be made of plastic, for example thermoplastic material. The contour of the selector shaft or the outer region or the outer layer are particularly advantageously applied to a core in a spraying process. A flattened round profile, for example in a D-shape, is an advantageous form for a core. This design, which differs from a circular shape, ensures that the core and outer area or outer layer are prevented from rotating.

It is possible to form the reinforcement in the area of the flattening of the round profile of the core or to arrange the core within the control shaft in this way. It is advantageous if the reinforcement does not protrude over the cross-section of the round profile, which would correspond to the continuous course of the cross-section without flattening. In other words, the shape and protrusion of the reinforcement should be coordinated with the flattening of the core.

For the most possible distortion-free spraying process of a aforementioned plastic control shaft, it is advantageous if essentially the Thickness of an outer layer of the switching shaft, which is sprayed around a core, remains the same. Deviations can only be made in the area of the flattening of the core. Finally, the reinforcement is advantageously injection molded here. The contour of the cams or cam disks should also be attached to the selector shaft in this spraying process.

It is advantageous if the layer thickness of an outer layer is small compared to the diameter of the core. This reduces the risk of the entire selector shaft being distorted after the core is overmolded as a result of cooling.

Another aspect for the design of the selector shaft or the arrangement of the reinforcement is that the reinforcing rib representing a mass concentration can be used to compensate for other mass concentrations which can otherwise cause warping when the selector shaft is sprayed. Such warping can be caused, for example, by the cams or cam disks usually being oriented rigidly in one direction or in an area. A center of mass line of the cams or cam disks can be determined. With regard to the axis of rotation seen from this center of gravity, the reinforcement should run in order to avoid or at least reduce warping due to its own mass when the selector shaft cools down after spraying. In this way, long switching shafts can be formed which, due to the rib-shaped reinforcement in certain configurations of the invention, are better able to withstand warping or bending during operation due to pressure forces and also after a spraying process for production. These and further features of preferred developments of the invention are evident from the claims and also from the description and the drawings, the individual features being implemented individually or in groups in the form of sub-combinations in one embodiment of the invention and in other fields, and can represent advantageous and protectable versions for which protection is claimed here.

Brief description of the drawings

An embodiment of the invention is shown in the drawings and is explained in more detail below. The drawings show in schematic form:

1 shows a side view of a possible selector shaft with a reinforcing rib and a large number of cam disks, FIG. 2 shows a cross section through the selector shaft at the location of a substantially rotating cam disk, and has a protruding cam.

Detailed description of the embodiment

In Fig. 1, a switching shaft 11 is shown in side view. 2 and 3 show sectional drawings at different points with differently designed cam disks. It can be seen how the long selector shaft 11 is formed by a basic profile 13. Various types of cam disks 15 are formed on the base profile 13. In the exemplary embodiment shown, the cam disks 15 basically have a maximum radius or are shaped out of a circular disk with this maximum radius. In the case of the cam disk 15 according to FIG. 2, an incision 16 is removed from the cam disk 15. In Fig. 3, the cam disc 15 consists essentially of a disc with a very small radius beyond the base profile 13. A projection 17 is formed on this disk.

The switching contacts 19 press against the cam disks 15 from below. Their compressive force or switching force is shown by the upward-pointing arrows on all cam disks 15. The switching contacts 19 can on the one hand be pure switching contacts which open or close. Furthermore, variable-distance switches can also be provided as switching contacts, for example for thermal expansion switches with pre-setting of a switching path. In this case, the cam disks 15 not only have stepped radii, but an evenly increasing or decreasing radius. The switching contacts 19 can thus be moved slowly and continuously as a function of an angle of rotation.

In the cross-sectional representations from FIGS. 2 and 3 it can be seen how the selector shaft 11 is constructed in detail. A core 21 with a flattened D profile is surrounded or surrounded by the base profile 13. injected. The base profile 13 has a flat 23, which is directed upwards in the drawings. It can thus be seen how the base profile 13 surrounds the core 21 with a uniform wall thickness.

In the middle of the flat 23, a reinforcing rib 25 is formed pointing upwards. This has an approximately rectangular cross section. It can be seen from FIG. 3 that it does not protrude beyond the radius of the other basic profile 13. From Fig. 1 it can be seen how it extends over the entire central region of the length of the selector shaft 11 and thus about 70% to 80% of the length of the selector shaft.

It can thus be seen that it is fundamentally possible to arrange such a reinforcing rib 25 at any point on the basic profile 13 of the selector shaft 11. The use of a flattened round profile with a D-shape of the core and / or base profile is particularly advantageous. This makes it possible to provide the reinforcing rib in the area of the flattening in such a way that it does not project beyond the other radius of the basic profile. Instead of a single reinforcing rib, it is also possible to arrange two or more reinforcing ribs in the area of the flattening.

Furthermore, it can be seen from the figures how the reinforcing rib 25 in the position according to the figures is arranged exactly opposite the switching contacts 19 and the forces caused by them. Thus, it can effectively prevent the shift shaft 11 from sagging. Since the control shaft 11 is usually supported at both ends, this risk of bending in the middle is greatest. In this respect, the reinforcing rib 25 is particularly advantageous in the middle in all cases. Furthermore, it can be seen from FIGS. 2 and 3 how the center of gravity of the cam disks 15 with the incisions 16 or the projection 17 cannot easily be precisely determined in each case due to their shape. However, it is certainly below the center of the control shaft 11, which forms the axis of rotation. In this respect, the reinforcement rib 25 can be used in the manufacturing process to achieve a certain center of gravity above the center point in comparison to an annular basic profile 13. As a result, the center of gravity of the cam disks 15 below the pivot point can be compensated to the extent that warping of the selector shaft during cooling after the spraying process is avoided by accumulation of mass or material on one side.

Overall, when designing the selector shaft 11 and the rotary switch or the switching contacts 19, it is advantageous to ensure that the main acting switching forces are aligned as uniformly as possible. This enables a reinforcement rib to be present at one point.

In order to provide designs with a plurality of reinforcing ribs, further flattenings could either be present on the core 21, which in turn enables the provision of further flattenings corresponding to the flattening 23 on the basic profile 13. A protruding reinforcing rib can then be provided in the region of each flattening. Furthermore, it is also possible to provide reinforcing ribs for a few or individual cam disks 15 from the point of view of mass balancing mentioned above. In this case, they should be positioned opposite their center of mass. However, it must then be ensured that the center of gravity does not deviate too far from the opposite side of the continuous reinforcing rib 25. Instead of the rectilinear reinforcement rib 25 according to the figures, it is also possible to offset the reinforcement rib in the area between individual cam disks 15 in the circumferential direction by a slight angle. However, this offset should not be too large so as not to impair the strength properties of the reinforcement rib for absorbing tensile forces too much.

Thus, in one exemplary embodiment of the invention, a switching shaft for a rotary switch can be created, which has molded cams or cam disks. On the outside of the selector shaft, a reinforcing rib is provided, which extends in the axial direction until just before the ends of the selector shaft. This reinforcing rib can absorb tensile stresses, which are caused by pressure forces from switching contacts, especially in the central region of the switching shaft. This prevents bending of the selector shaft.

Claims

claims

1. selector shaft for rotary switches, the selector shaft (11) having molded-on cams (17) or cam disks (15), characterized in that at least one reinforcement in the form of a rib (25) is integrally formed on the outside of the selector shaft in the axial direction for receiving of tension against bending of the selector shaft.

2. Switching shaft according to claim 1, further characterized in that the reinforcement (25) extends over a wide central region of the switching shaft (11), preferably until shortly before the respective end of the switching shaft, preferably in the region with reinforcement and / or in the region without reinforcement there is a substantially constant cross section.

3. control shaft according to claim 2, characterized in that the reinforcement (25) is continuous without interruptions, preferably with constant strength.

4. Control shaft according to one of the preceding claims, characterized in that the reinforcement (25) of the control shaft (11) projects with approximately 10% to 30% of the total diameter of the control shaft.

5. selector shaft according to one of the preceding claims, characterized in that the reinforcement (25) points in the direction of force which is exerted in a certain rotational position on the selector shaft (11) in which on the cams (17) or cam disks (15) the strongest pressure forces are exerted of switching contacts (19) or the like, which are actuated or moved by the cams or cam disks.

6. Switching shaft according to one of the preceding claims, characterized in that it has at least one outer region or an outer layer (13) made of plastic.

7. selector shaft according to claim 6, characterized in that it consists of thermoplastic material, preferably also a core (21) of the selector shaft (11) which is overmolded.

8. selector shaft according to claim 6 or 7, characterized in that the selector shaft (11) has a core (21) which is injection-molded with plastic to produce the selector shaft, preferably the selector shaft and / or the core having a flattened round profile, in particular is a D profile.

9. selector shaft according to claim 8, characterized in that the reinforcement (25) in the region of the flattened portion (23) of the round profile of the core (21) is formed, preferably the reinforcement does not protrude beyond the cross section of the round profile, which is the steady without flattening Corresponds to the course of the cross section.

10. control shaft according to claim 8 or 9, characterized in that, except for flattening (23), the layer thickness of an outer layer (13) which is injection molded around a core (21) of the control shaft (11) is constant, in particular is small compared to the diameter of the core.

11. Switching shaft according to one of the preceding claims, characterized in that the reinforcement (25) is formed in the circumferential direction in a region of the switching shaft (11) which is opposite to the area in which a mass concentration of the cams (17) or cam disks (15) lies, this being in particular the center of gravity of the cams or cam disks with respect to the cross section.