DE2403565A1 - Rotary stepping switch with latching mechanism - has latch resetting spring with specified latching positions before resetting - Google Patents

Abstract

The rotary stepping switch has a latching and stopping mechanism and a resetting spring mounted in the space of this mechanism. The resetting spring arrangement permits a delocked switching position after a preset number of latched switching positions. In the delocked position the resetting spring arrangement provides resetting into the previous switching position. Preferably the resetting spring has a resetting stop, effecting the return into the previous switching position. The delocking in the preset switching position may be provided by an oblique element which may be formed by filling the corresponding latching gap. The resetting spring may abut a stationary stop, while the reset effecting stop may be connected to a rotary part.

Description

Return indexing mechanism The invention relates to a step rotary switch with a locking and stop mechanism. The need for the invention is electrical or electronic devices that are switched in both continuous and pulsed operation e.g. to check or measure the battery voltage. Here the test or measuring device may only be connected to the device for a short time, so the rotary switch does not remain in the corresponding switch position. One The invention can therefore be used in radiotelephones or avalanche search devices given.

In a known switching device for an avalanche search device a multi-step rotary switch with detent positions for setting the channels and a second Switch with an on-off function for checking and measuring the battery voltage intended. The known switching device does not offer the security that the Test switch does not remain in its ON position.

A so-called springback is a significant improvement achieved in which a non-latchable switch position in the previous latchable Switch position can spring back. This exists in detail Spring-back device from a coil spring arranged in a housing, which has one end at a stationary part and mounted with the other end in a slot of the actuating shaft is. So that a spring back from the on-switch position to the previous one that can be latched Switch position takes place, the ON switch position must not be lockable.

Such a spring-back device offers the security that the switch from one switch position to the previous switch position is automatic springs back, but requires the construction of the step rotary switch and spring back device a certain installation space, which is undesirable for many possible applications or is not given. In particular, in the context of the miniaturization of components the construction height does not exceed a certain value.

It is the object of the invention to provide a switching device from a step rotary switch and to create a spring-back device that allows an extremely compact structure, as is required for the miniaturization of components. This task will in a step rotary switch of the type mentioned according to the invention thereby solved that arranged in the space of the locking and stop mechanism a locking spring-back is, in the case of the switch positions which can be latched after a switch position which cannot be latched follows, which can spring back into the previous switch position. With the step rotary switch according to the invention is not an additional one Space required, which would increase the height of the switch. Rather, the invention the already existing installation space of the locking and stop mechanism for the installation of the locking resilience exploited.

This makes it possible to use a rotary switch with latching spring-back to create in miniature construction.

So that a spring back from the nth lockable switch position / the (n + l) -th non-latchable switch position takes place, is according to an advantageous development of the invention in the area of the (n + l) -th switching position instead of a locking gap Arranged drainage slope. This drainage slope can automatically return to itself enable from the (n + l) -th switch position to the n-th switch position that can be locked, since the run-off slope creates an unstable position for the locking and holding element. In order to However, a self-locking of this unstable situation is excluded, is in the locking and stop mechanism arranged a return spring, the switch of with security the (n + l) -th returns to the n-th switching position. The drainage slope can be in the simplest way by filling in the corresponding snap-in gap of the snap-in contour of the Remainder be made.

The installation of the return spring in the latching and stop mechanism can according to Further development of the invention take place in two ways: On the one hand, it is possible that the return spring is supported on at least one stationary stop and the with her in the sense of a spring back cooperating stop with is connected to a rotatable part. On the other hand, the return spring can with connected to a rotatable part and with it in the sense of a springback cooperating stop be arranged stationary. The choice of one or the other Embodiment is on the one hand dependent on the size of the available Installation space and on the other hand from the desired level of security with which the return from the (n + l) -th to the n-th switch position.

In a preferred embodiment of the invention, the return spring is a helical compression spring in a circular fixed groove along its length is guided and is supported with one end on a stationary stop, while the other end of the screw is in the non-latching switch position with a rotatable stop cooperates in the sense of a spring back. This embodiment has the advantage of the simplest construction with a high degree of security for the Springback. However, it requires a certain installation depth for the guidance of the Helical compression spring.

In a further preferred embodiment, the return spring is designed as a leg spring running along a circular collar on the housing bottom is performed and in the lockable switch positions with both spring legs supported on stationary stops, while in the non-latchable switch position the one Spring legs with a rotatable stop in the sense a springback cooperates. Such an embodiment requires due of radially directed spring legs a sufficient installation volume in the radial direction. Because of the spring coils extending in the axial direction must also be in this Sufficient installation space is available in the direction of With the same available Installation space allows for one with the leg spring opposite the helical spring achieve greater spring effect, but the assembly of the leg spring is designed more complex, since they are in the latching switch positions with both spring ends supported on stationary stops.

In a preferred embodiment of the invention according to the second type, at least a piece of bent spring wire is used as the return spring, which is held in two openings in the rotor and guided by it. This spring wire then acts in the non-latchable switching position with a stationary stop in the sense of a spring back together. The assembly of the return spring is in this The case is more complex, because of the need to introduce the spring wire into the two openings while bending the wire at the same time. The usage However, it has spring compression wire instead of a screw spring or leg spring the advantage of taking up little space and being easy to manufacture. To the to ensure the necessary safety for the springback, have to but if necessary two such bent pieces of spring wire can be used.

This also limits the rotary movement in the (n + l) -th switch position the actuating shaft is accomplished, a rotatable stop acts with a stationary stop together. Existing stops can be used for this be used.

Further details of the invention are explained with reference to the drawing, from which preferred exemplary embodiments can be seen. They show: FIG. 1 in Top view of the latching resilience of a rotary step switch according to the invention; FIG. 2 shows, in section along the section line A-B, the locking resilience shown in FIG. 1; FIG. 3 shows, in section along the section line C-D, a detail of that shown in FIG Snap-back suspension; FIG. 4 shows a plan view of another locking resilience for one Rotary step switch according to the invention; Figure 5 in section along the cutting line E-F shows a detail of the locking resilience shown in FIG. 4; figure 6 in a plan view of a further latching spring-back for a step rotary switch according to FIG the invention; FIG. 7 shows in section along the section line G-H that shown in FIG Latch spring back.

In the latching and stop mechanism shown in FIGS. 1 to 3 10, a housing 20 is used to accommodate a rotatable part 30, a stop ring 40 and a helical compression spring 50. The housing 20 carries on its inside a latching contour made up of gaps 21 and teeth 22, with which at least one is under spring pressure standing holding member in the form of a locking ball 60 in the sense of a definition of the switching positions works together. This locking ball is in a radially directed bore 31 together out with a helical compression spring 70 in the rotatable part 30, so that at a rotational movement of this part, the locking ball 60 in the locking gaps 21 of the locking contour allows a certain number of lockable switch positions. In the off The embodiment shown in FIG. 1 results in a total of 11 (n) such latchable ones Switch positions.

The twelfth ((n + l) -th) switch position, on the other hand, is characterized by / from the fact that it cannot be locked, but rather into the previous eleventh (nth) Switch position can spring back when in a bore 23 of the housing sleeve 24 guided actuating shaft 80 is released. To realize this locking resilience is used in the exemplary embodiment of FIGS. 1 to 3 a helical compression spring 50, which is guided in a circular, stationary groove 90. The boundary walls this groove are formed by the housing base 25, the housing collar that is already present 26, which serves as a support bearing for the rotatable part 30, and the stop ring 40, which as part of the stop mechanism 10, the rotary movement of the actuating shaft 80 limited. This limitation of the angle of rotation is due to the interaction of the stop lug 41 of the stop ring 40 accomplished with a rotatable stop pin 100, which is arranged in a bore 32 of the rotatable part 30.

While one end of the screw of the helical compression spring 50 is in can support each switching position on the stationary stop lug 41, this works the other end of the screw in the twelfth, non-latching switch position with the rotatable stop pin 100 in the sense of a spring back together. This is it is necessary that in the area of the twelfth switching position instead of a locking gap 21 a slope 27 is provided so that the locking ball 60 in the twelfth Switching position cannot lock into a detent gap. To produce the drainage slope 27, a filler part 28 can be used, which completely covers the original locking gap 21 fills out.

However, it is also possible to remove the slope 27 from the outset to provide the latching contour of the housing 20, the transfer molding or injection molding process can be produced.

As can be easily seen from FIG. 1, the latching spring-back can can be implemented in any switching position if the run-off slope 27 is formed by an adjustable filling part 28; because the stop ring 40 can easily adjustable by having one or more lugs is incorporated into the latching contour of the housing 20 in a self-retaining manner. The stop nose 41 then comes to rest at the desired location in this case. In this embodiment the stop ring 40 is movably arranged on a piece of its circumference, there the helical compression spring 50 in the pressed state with its block length as a widening the stop lug 41 acts. In order to be able to achieve all twelve switch positions, the stop ring 40 can be adjusted by the block length of the helical compression spring Move 50 on.

For this purpose, the stop ring 40 is provided with a further one to the outside directed stop lug 42, which is incorporated in a slot of the filling part 28 is. The boundary surfaces then act as stop surfaces for the stop nose 42 at the beginning and at the end of the filling part slot.

In the embodiment shown in FIGS the return spring, namely the helical compression spring 50, is supported on a movable, adjustable stop, the stop lug 41, while with her in the sense of a Resilience cooperating movable stop, the stop pin 100, with a rotatable part 30 is connected. This Construction principle is also realized in the embodiment of Figures 4 and 5, in which but instead of the helical compression spring 50 one in the installation space of the latching and stop mechanism 110 arranged leg spring 150 is used. (The ones used in Figures 4 and 5 With the exception of the preceding number 1, the designations correspond to the designations of the Auführungsbeispiels according to Figures 1 to 3) The leg spring 150 is along a circular housing collar 126 out and is supported in the latching switch positions with both leg ends 151, 152 on stationary stops, the stop pins 142, 143 of the stop ring 140, while in the non-latchable switching position one spring leg 152 with a rotatable stop, the stop pin 200, cooperates in the sense of a springback. Is in the nth switch position the rotatable stop pin 200 in the indicated by dash-dotted lines Position. The locking ball 160 is under the action of the helical compression spring 170 in the snap-in gap 121 located to the right of the drawn-in snap-in ball is incorporated. During the transition to the (n + 1) th switching position, the locking ball 160 comes to the drainage slope 127 and the stop pin 200 with entrainment of the spring leg 152 into the solid line Line marked position in which the stop pin at the same time on the stop lug 141 of the stop ring 140 comes to rest. This causes the rotation of the in the bore 123 of the housing sleeve 124 mounted actuating shaft 180 on the desired angle of rotation limited.

When you release the operating shaft 180 get the rotatable Stop 200, the spring leg 152 and the locking ball 160 under the action of the spring the leg spring 150 in the n-th switching position, i.e. in the original position. The stop mechanism can be implemented in the usual way. In the one shown in FIG In the exemplary embodiment, the rotatable stop 200 engages in one of the boundary walls the stop ring 140, the housing bottom 125 and the housing collar 126 are formed Circular groove 190 until the stop pin rests against the stop lug 141.

As in the embodiment shown in FIG in the embodiment according to FIG. 4, the 1st switch position from the one to the left located 2nd switch position can be reached. For this it is necessary that in the 2nd switch position the one drawn with dash-dotted lines rotatable stop pin 200 on the other spring leg 151 comes to rest. For example, in the case of a latching and stop mechanism 110 with ten latchable ones Switching positions possible that the snap-back springing from the twelfth to the eleventh or takes place from the first to the second switching position.

In contrast to the exemplary embodiments shown in FIGS. 1 to 5 is the embodiment shown in Figures 6 and 7 on another Construction principle, namely here the return spring is rotatable with a Part connected and the stop that interacts with it in the sense of a springback fixed in place. It deals So this is a kinematic one Reversal of the construction principle according to FIGS. 1 to 5. In the exemplary embodiment 6 and 7, the return spring is formed by at least one piece of spring wire 250 formed, which is held in the rotatable part 230 and guided by this. This piece of spring wire acts in the non-latchable switch position with a stationary stop, the stop tab 311 of the stop ring 310, in the sense of a Spring back together. Otherwise, the effect of the locking and stop mechanism corresponds 210 of those of the locking and stop mechanisms 10, 110, so that a more detailed explanation can be omitted at this point. To hold the spring wire piece 250 is this incorporated into two openings 233, 234 by a corresponding bend. the The (n + 1) -th non-latchable switch position can be seen in the one shown in FIG Embodiment by a rotational movement of the rotatable part 230 against clockwise. During this rotary movement, the comes under the effect of the helical compression spring 270 standing locking ball 260 on the drainage slope 227 of the Filler part 228 with simultaneous stressing of the spring wire piece 250 on bending, since the stop tab 311 prevents the piece of spring wire from being carried along. At the same time comes the rotatable stop, specifically the stop pin 300, on the stop lug 241 of the stop ring 240 to rest, so that the further rotary movement of the actuating shaft 280 is limited. The other designations in FIGS. 6 and 7 again correspond With the exception of the preceding number 2, the designations described above Characters. A further explanation in connection with these designations can be given therefore omit at this point.

To increase the spring action of the in Figures 6 and 7 in the form of a Spring wire piece present return spring and thus to increase security a second piece of spring wire 250 may be required for the spring back to be arranged, which is also held and guided by the rotatable part 230. It is also possible, in turn, by adjusting the individual elements to form the locking spring-back Parts are achieved that the springback from the (n + 1) -th to the n-th switching position or from the (n + 1) -th to the 1st switching position.

List of reference numerals 10, 110, 210 latching and stop mechanism 20, 120, 220 housing 21, 121, 221 gap 22, 122, 222 tooth 23, 123, 223 bore 24, 124, 224 housing sleeve 25, 125, 225 housing base 26, 126, 226 housing collar 27, 127, 227 drainage slope 28, 128, 228 filling part 30, 130, 230 rotatable part 31, 131, 231 32, 132, 23J bore 233, 234 opening 40, 140, 240 stop ring 41, 141, 241 stop lug 42 stop lug 142, 143 stop pin 50 helical compression spring 150 leg spring 151, 152 spring leg 250 spring wire piece 60, 160, 260 detent ball 70, 170, 270 helical compression spring 80, 180, 280 actuating shaft 90, 190, 290 groove 100, 200, 300 stop pin 310 stop ring 311 stop tab 10 claims

Claims (10)

Claims 1.) Step rotary switch with a latching and stop mechanism, d u r c h g e k e n n n z e i c h n e t that in the installation space of the locking and arcing mechanism (10, 110, 210) a locking resilience is arranged in which can be locked after n Switch positions a non-latchable switch position follows that in the previous one Switch position can spring back. 2.) Rotary switch according to claim 1, characterized in that im Latching and stop mechanism (10, 110, 210) of the switch a return spring (50, 150, 250) is arranged with a stop (41, 141, 311) in the sense of a spring back cooperates from the (n + 1) -th to the n-th switching position. 3.) Rotary switch according to claim 1 or 2, characterized in that that in the area of the (n + 1) -th switch position instead of a detent gap (21, 121, 221) a drainage slope (27, 127, 227) is arranged. 4.) Rotary switch according to claim 3, characterized in that the Drainage slope (27, 127, 227) by filling in the corresponding locking gap (21, 121, 221) is established. 5.) Rotary switch according to one of claims 1 to 4, characterized in that that the return spring (50, 150) is at least one stationary stop (41, 142, 143) and the one that interacts with it in the sense of resilience Stop (100, 200) is connected to a rotatable part (30, 130). 6.) Rotary switch according to one of claims 1 to 4, characterized in that that the return spring (250) is connected to a rotatable part (230) and the stop (311) which cooperates with it in the sense of a spring-back is arranged in a stationary manner is. 7.) Rotary switch according to one of claims 1 to 5, characterized in that that the return spring is a helical compression spring (50) which is in a circular, fixed groove (90) is guided along its length and with one end at one stationary stop (41) supported, while the other end of the spring is not locked in the Switching position with a rotatable stop (100) in the sense of a spring back cooperates. 8.) Rotary switch according to one of claims 1 to 5, characterized in that that the return spring is a leg spring (150) along a circular Federal is guided on the housing base (125) and is in the lockable switch positions supported with both spring legs (151, 152) on stationary stops (142, 143), while in the non-latchable switch position of the one spring leg (151) with a rotatable stop (200) cooperates in the sense of a spring back. 9.) Rotary switch according to one of claims 1 to 4 and claim 6, characterized in that the return spring has at least one piece of bent spring wire (250) is held in two openings (233, 234) in the rotatable part (230) and in the non-latchable switch position with a stationary stop (311) cooperates in the sense of a springback. 10.) Rotary switch according to one of claims 1 to 9, characterized in that that in the (n + 1) -th switching position a rotatable stop (100, 200, 300) with a stationary stop (41, 141, 241) in the sense of limiting the rotary movement the actuating shaft (80, 180, 280) cooperates.