CZ298083B6 - Switching clock with 24-hour switching roller - Google Patents

Abstract

The present invention relates to a switching clock having a rotatably driven switching roller provided with several switch elements (4, 10) arranged on a circular track. Said switch elements (4, 10) can be set in a corresponding switching position in order to perform a switching process. The switch elements (4, 10) are arranged on radially disposed switch arms (5, 11). The switch arms (5, 11) pivot about axes tangential to a switch ring (3) to move the switch elements. In order to achieve smallest possible structural size of the device at simultaneous provision of short switching times, said switch ring (3) consists of two separate support rings (1, 2), whereby said switch elements (4, 10) are separated into two equally sized groups having the same number of the switch elements (4, 10) The first group of the switch elements (4) is connected to the first support ring (1) while the other group of the switch elements (10) is connected to the second support ring (2). The switch arms (5) of the first group of the switch elements (4) and the switch arms (11) of the second group of the switch elements (10) are arranged in a common plane alternately around the switch ring (3). The switch elements (4, 10) lie axially behind one another and are spaced at least in the radially outer area. The space is large enough so that the switch elements (4, 10) do not cover each other.

Description

Timer with 24-hour switching cylinder

Technical field

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a switchgear with a rotatably driven switch cylinder having a plurality of switch elements arranged on a circular path which are adjustable to at least two switch positions for controlling the switching process and which are connected to a switch ring lying radially by radially arranged switch arms. within the circular path of the switching elements, wherein the switching arms, when adjusting the switching elements, perform a pivotal movement about a rotational axis extending substantially tangential to the switching ring, and wherein the switching ring consists of two separate carrier rings and the switching elements are equally divided into a first group connected with a first support ring, and to a second group associated with the second support ring.

BACKGROUND OF THE INVENTION

DE 28 13 069 C2 discloses a switching clock of the above type having a rotatably driven switching cylinder. This switching cylinder, referred to herein as a drum, is provided with a plurality of switching elements arranged on a circular path. These switching elements serve to control the switching process in the clock and for this purpose they can be moved to at least two possible switching positions. In order to produce such a switching cylinder in a space-saving size and as cheaply as possible, in this known construction, the switching elements are inseparably connected to a switching ring radially disposed in a circular path by means of approximately radially arranged switching arms. This unit, referred to as a switching disk and consisting of switching elements with respective switching arms and a switching ring, can be manufactured by injection molding and, since it is a one-piece part, is also easy to assemble. As a result of the one-piece design of the unit, a relatively large number of switching elements can be arranged in the device on a predetermined diameter of the switching cylinder, thereby providing a relatively large number of switching possibilities. In practice, it has been shown that for switching cylinders with a diameter of about 5 cm, 30-minute switching intervals can be set for a 24-hour clock. It. means that, for a 24-hour 360 ° switching cylinder, forty-eight switching elements are provided. In order to prevent the switching elements from tilting in the circumferential direction during switching, the switching arms of the individual switching elements are guided by means of individual grooves of the switching cylinder which are open on one side, from which the shaped arms corresponding to their radially outer end project. A respective switching element bears against the outer end of each of the switching arms, which is thus exactly moved in its circumferential direction when the switching cylinder is rotated. The switching arms must have a certain radial length in order to allow sufficient adjustment movement without damaging the switching arms. Therefore, the switching ring also has a substantially smaller diameter than the circular path on which the switching elements are arranged at the outer end of the switching arms. The consequence of this is that the number of switching arms arranged on the switching ring in the same plane cannot be arbitrarily increased, since otherwise the stability of the switching arms will be significantly reduced as the width of the switching arms decreases. It has been found that with a diameter of the switching cylinder of about 4.5 cm, hardly more than the 48 switching elements can be arranged on the switching ring in order to ensure sufficient stability thereof. A larger number of switching elements would require an increase in the overall diameter of the switching cylinder and hence the diameter of its switching ring. The same also applies to even smaller switch cylinder designs with diameters smaller than the above 4.5 cm. With such a reduction in the entire switching cylinder, the switching arms would be so weakened in the radially inside region of the switching ring that sufficient stability of the switching arms could not be safely ensured.

Further, DE 28 13 194 A1 discloses a disk-shaped program carrier for controlling the switching processes of an electric time clock. This program carrier forms a switch-on state when assembled

Cylinder for time switches of the above mentioned kind. The switching cylinder comprises a two-part switching ring formed of two separate support rings on which the switching elements are displaceably arranged in the axial direction of the axis of rotation. In this case, the switching elements are divided into two groups of equal number and are assigned in groups to each of the switching rings. The switching elements are connected to the associated support ring by radially extending switching arms and are arranged in groups in succession in the direction of their circumference. The switching arms of the two groups of switching elements cross in dependence on the switching position of the switching elements in the radial region between the two support rings and the external switching elements. In order to avoid a collision of the switching arms, there is always a gap between the two adjacent switching arms of each group whose width in the circumferential direction corresponds to the width of the switching arm of the other group, increased by a certain air gap. That is, the switching arms of one group in the assembled state of the carrier rings forming the switching ring, all along their radial length between the switching arms of the other group, in the assembled state of the carrier discs constituting the switching ring, find a location in the circumferential direction with little play. This in turn depends on the fact that both the width of the gaps and the width of the switching arms are reduced from the outside towards the inside, so that even here the carrying cross-section of the switching arms in the radial inner region has to be particularly large. the larger total number of switching elements be very small in order to achieve this large number and / or small construction size of the switching cylinder. However, the support cross-section of the switching arms cannot be arbitrarily reduced for reasons of stability, since the switching arms would lose their elastic properties and the switching arms would tend to break if the switching positions of the respective switching elements are changed frequently. This, in turn, results in the fact that a given size cannot be further reduced for a given number of switching elements or that the number of switching elements is limited at a given size.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is an object of the present invention to provide a switching clock of the kind described in such a way that a plurality of switching elements can be used to achieve shorter switching times, with a small size and ensuring their simple and cheap manufacture.

This object is solved according to the invention and the essence of the solution is that the switching arms of the first group of switching elements and the switching arms of the second group of switching elements are adjacent to each other supporting rings forming the switching ring. and the second switching elements, they extend axially one behind the whole of their radial length in the direction of the axis of rotation of the switching cylinder, and at least in the outer radial region of the switching elements they have an axial distance relative to each other. The switching elements, when switching to one of their switching positions, cannot limit each other even if the switching arms partially overlap in the circumferential direction.

In an embodiment of the invention, a plurality of switching elements may be provided on the outer periphery of the switching cylinder of the switching clock at a given diameter of the switching cylinder. Although the switching elements have a narrower design in the circumferential direction than the smaller number of switching elements, their circumferential width of one to two millimeters is of sufficient size to allow the switching elements to be safely and easily moved to the desired switching positions.

The switching arms, which are axially connected in the direction of the axis of rotation of the switching cylinder over their entire radial length, can still have sufficient width and thus stability to be carried out even in the region of a radially inside switching ring due to the division into two groups in the circumferential direction. a large number of switching processes without damaging the switching arms. Due to this basic arrangement of the switching arms axially one behind the other, the arms can have at least a partial overlap in the radially inner region of the switching ring, so that a larger number of switching arms can be used than in the known switching cylinders.

-2GB 298083 B6

In order to achieve such an arrangement of the switching arms, according to the invention, the switching ring is divided into two separate support rings. The switching elements according to the invention are divided into first and second groups of equal number of switching elements, the first group of switching elements being connected to the first support ring and the second group being connected to the second support ring by means of the switching arms. By placing the two support rings on one another, a switching ring is formed. In this assembled assembled position of the two support rings, the switching elements of the first and second groups, at the same switching position, lie in a common plane running substantially at right angles to the axis of rotation of the switching cylinder. The spacing of the switching elements and their circumferential width are selected such that the switching elements of the first group and the switching elements of the second group follow in the circumferential direction alternately. In order to avoid collision of the first and second switching arms when the respective switching elements are moved to different switching positions, the switching arms have at least a radially outer region at a distance which is defined so that the switching arms of the first group and the arms of the second group cannot restrict each other. The switching arms associated with the two switching rings can also have an axial distance from one another in the radially inner region in the direction of the switching ring. However, this is not absolutely necessary.

According to the invention, it is thus possible to produce a switching cylinder of very small diameter, which is, for example, provided with 96 switching elements. When the switching cylinder is fully rotated 360 ° per day, switching operations can be switched on at a quarter-hour interval. With switching cylinders of comparable size, only half an hour of switching has been possible so far, since only a maximum of 48 switching elements could be arranged. Conversely, if only 48 switching elements were provided in the switching cylinder according to the invention, the switching cylinder according to the invention and hence the entire switching clock could have substantially smaller constructional dimensions, and consequently it is possible to use the clock in a smaller space. for example in a switch cabinet.

In order to achieve a low construction height, according to claim 2, the switching arms of the first group of switching elements and the second group of switching elements are radially diverging from the switching ring. That is, with the switching elements of the first and second groups lying in the same plane, the switching arms of, for example, the first group are deflected from the switching elements from this common plane to the axial direction, while the switching arms of the second group are inclined axially in the opposite direction . Thus, in the region of the two bearing rings, according to claim 2, in this embodiment, the pivot arms are axially immediately following one another in the axial direction. This embodiment according to the invention makes it possible to achieve a very small size, in which the mutual limitation of the switching arms when moving them to different switching positions is completely eliminated.

According to claim 3, the individual switching elements can be connected with radially outer end portions of the switching arms by means of adjacent V-shaped brackets adjacent to one another. This results in a radially yielding connection of the switching elements by means of an associated switching arm to the respective support ring. As a result of this radially yielding connection, a radially inwardly facing bearing nose can be arranged on the switching elements according to claim 3, by means of which the switching elements are held in their current switching position on the switching cylinder receiving housing in their current position. This means that the switching elements can be radially resiliently deflected for insertion or withdrawal on the receiving housing due to the V-shaped support brackets.

According to claim 4, a particularly stable design of the switching arms is achieved in that the arms and the carrier stirrups have a substantially constant width over their entire radial length in the circumferential direction. In this case, the overlap in the radially inner region of the support rings or the switching ring is particularly large, while it is zero in the radially outer region of the support stirrups, so that the support stirrups together with the switching elements mounted on the radially outer side in circumferential direction have space.

-3GB 298083 B6

By means of guide bridges according to claim 5 arranged on the outer periphery of the housing housing cover, the number of which corresponds to the number of switching elements, it is ensured that the switching elements are guided together accurately when the switching cylinder is rotated in the circumferential direction. In order to be able to firmly connect the switching elements in their respective switching positions to the housing cover, a fastening element is provided between two guide bridges adjoining the circumferential direction, with which the individually assigned bearing nose can be brought into positive contact and thus secured.

To this end, according to claim 6, the distance between two adjacent guide bridges is approximately equal to the circumferential width of the contact nose of the switching element, thereby ensuring accurate guidance of the switching elements between the guide bridges in the circumferential direction. Among other things, this also means that the processes connected by means of these switching clocks or switching elements are time-adjustable with high accuracy.

The embodiment according to claim 7 allows precise coaxial mounting of the two support rings with respect to the base housing. To this end, the first support ring is provided with a raceway first bearing bridge extending towards the housing cover, through which the first support ring, when assembled, abuts each annular groove of the housing. On the other hand, the second carrier ring is provided with a raceway second bearing bridge extending towards the base sleeve, wherein in the assembled state the second carrier ring bears against the raceway two circular grooves of the base case. By this connection of the carrier rings with the cover on one side and with the base sleeve on the other side, the positions of the carrier rings can be freely adjusted, so that they can be aligned in a simple manner with the bearing noses of the respective switching elements. The annular grooves are arranged concentrically with respect to the axis of rotation of the switching cylinder in the bearing housing, while the raceways are arranged concentrically with respect to the bearing rings. It goes without saying that the two support rings may also be in a form-fit relationship with each other in which, for example, only one of the support rings is housed in a receiving sleeve in one corresponding circular groove of the cover or base sleeve. It is further understood that the arrangement of the bearing bridges on the carrier rings and the arrangement of the circular grooves can also be reversed.

By the embodiment according to claim 8, a very simple mounting of the housing is provided. For this purpose, the cover, in the assembled state, is centered and rotatably supported on the base housing on which it is fixedly secured by means of locking elements.

By means of a time dial, which according to claim 9 is arranged on the raceway surface of the basic housing and on the axial outer surface of the housing, the switching cylinder according to the invention can be used variable in different switching hours and for different applications. , which is used for setting and programming time switches. In this case, the time dial on the axial outer surface of the housing cover serves to check the operations performed on the timer in the disassembled state.

By means of an embodiment of the invention, a switching clock is provided in which a large number of switching elements can be selected so that, for example, a quarter-hour switching process can be set without the need to increase the switching cylinder to accommodate the individual switching elements. for switching cylinders suitable for maximum switching at half-hour intervals. Switching rollers with a predetermined number of switching operations can also be constructed in much smaller dimensions than switching rollers according to the prior art.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS In the following, the invention is described in more detail with reference to the accompanying drawings, in which Fig. 1 is a partial cross-section of the first and second support rings with the switching elements shown in FIG.

them arranged. Fig. 2 shows the joined support rings of Fig. 1, viewed from above from Fig. 1. Fig. 3 is a perspective partial cross-section of the housing of the device housing, the base sleeve and the two support rings of Figs. 1 and 2. Fig. 4 is a partial view IV of Fig. 5 of the housing cover of Fig. 3. Fig. 5 is a sectional view of the VV of Fig. 4. Fig. 6 is a partial view VI of Fig. 7 of the base housing of Fig. 3. Fig. 7 is a cross-sectional view taken along line VII-VII in Fig. 6. Fig. 8 is a cross-sectional view of a switching cylinder according to the invention with its switching elements in different switching positions. Fig. 9 shows the switching cylinder of Fig. 8, the switching elements of which are in other different positions. FIG. 10 is a cross-sectional view of a switching cylinder with two support rings, with a further arrangement of the switching arms on the support rings.

DETAILED DESCRIPTION OF THE INVENTION

Fig. 1 shows a first support ring 1 which, in the position shown, simultaneously represents the upper support ring of the switching cylinder 50 (Fig. 8). A second, lower support ring 2 is associated with this first support ring 1 so that the two support rings 1 and 2 together when assembled form a switch ring 3 (FIG. 2).

As is apparent from FIG. 1, a plurality of switching elements 4 are provided on the outer periphery of the upper support ring 1, which are connected to the upper support ring L by means of the switching arms 5. For radially resilient connection of the switching elements 4 to the respective switching arm 5 Supporting stirrups 7 are provided with radially outer end portions 6 of the switching arms 5 and the respective switching elements 4, which are approximately V-shaped and inseparably connected to the switching arms 5 and the switching elements 4. As can be seen further from FIG. the ring 1 in the region of its outer edge, an upwardly directed and circulating support bridge 8, the function of which will be described in further detail below. In the embodiment described, starting with the first support ring 1, the switching arms 5 are arranged obliquely upwards with respect to the horizontal plane defined by the first support ring 1. The switching arms 5 are arranged on the outer periphery of the first support ring 1 approximately in the region of its lower edge 9 .

The lower, second support ring 2 is also provided with a plurality of switching elements 10 which are inseparably connected to the second support ring 2 by means of a switching arm 11 and a carrier yoke 12. Furthermore, the second support ring 2 has a vertical downwardly directed circulating bearing a bridge 14, the function of which will be described in more detail below. As can be seen from FIG. 1, the switching elements 4 and 10 of the two support rings 1 and 2 are each spaced apart in a circumferential direction, their circumferential spacing being such that the two support rings 1 and 2 with their switching elements 4 are arranged. or 10, respectively, can be pushed into each other until the two support rings 1 and 2 abut one another.

Fig. 2 is a top view 11 in which the support rings 1 and 2 are slid. It can be seen from FIG. 2 that in this position the respective switching elements 4 or 10 are arranged alternately next to each other and almost free of play in the circumferential direction. It is further evident from FIG. 2 that the switching arms 5 and 1.1 overlap in the circumferential direction at least partially in the circumferential direction with respect to the switching ring 3 formed by the two support rings 1 and 2. For better understanding, the switching arms 11 of the carrier ring 2, which are shown in FIG. 2 as being arranged below the switching arms 5 of the carrier ring 1, are marked with hatched lines. Approximately in the radially outer region of the outer end portions 6 of the switching arms 5 or the outer end portions 13 of the switching arms 11, the switching arms 5 and 11 are alternately adjacent to one another in the circumferential direction. The same applies to the support stirrups 7 and 12 arranged between the outer end portions 6 and 13 of the associated switching arms 5 and 11, respectively, and between the respective switching element 4 and 10, respectively.

As is further evident from FIG. 1, the switching arms 11 extend obliquely downwardly from the second support ring 2 with respect to the horizontal plane defined by the second support ring 2.

That in the coupled state of the carrier rings 1 and 2 forming the switching ring 3, the switching arms 5 and 11 in the axial direction of the axis of rotation 51 of the switching ring 3 diverg from each other so that their end portions 6 and 13 have axial spacing relative to each other. . Since the switching arms 5 and 11 in the radially inner region of the support ring 1 and 2 lie directly one behind the other in this axial direction, the switching arms 5 and 11, although partially overlapping, can be pivoted to the switching limit in the radial inner region of the ring 3 in the direction shown by the two-way arrows 16 and 17, respectively (FIG. 1), in order to adjust the switching positions.

This ensures that the switching arms 5 and 11, with their switching elements 4 and 1,0, can be brought into different switching positions without the restriction of the adjacent switching arms 5 and 11, respectively, by the diverging arrangement of the switching arms 5 and 11. 1_1. The divergent arrangement of the switching arms 5 and 11 is provided in such a way that the switching elements 4 and 10 can be brought to the desired upper and lower end positions in order to be able to initiate corresponding switching operations.

As can be seen further from FIG. 1, the two V-shaped brackets 7 and 12 on which the switching elements 4 and 10 are arranged have different designs. The radially inner arm 7/1 of the yoke 7 is longer than the inner arm 12/1 of the yoke 12. Thus, the diverging arrangement of the switching arms 5 and 11 is aligned so that the switching elements 4 and 10, when the two carrier rings 1,2 are connected, can be adjusted to a common plane given by the plane of the carrier rings 1, 2 without the switching arms 5 and 11. interfered with each other.

FIG. 3 is a perspective cross-sectional view of the two support rings 1 and 2, showing, for example, one of the switching elements 4 and 10 respectively with the respective support bracket 7 and 12, and inseparably connected thereto, on each support ring 1 and 2 respectively; Furthermore, it is apparent from FIG. 3 and indicated by thin broken lines that, in the position where the support rings 1 and 2 abut, the switching arms 5 and 11 lie in the direction away from their support ring 1 and 2 completely axially over one another. The two switching arms 5 and 11 can, in their radially inner end portions, contact each other approximately in the dividing plane 18 of the two support rings 1 and 2. In the neutral middle position of the two switching elements 4 and 10 with their switching arms 5 and 11, also shown in FIG. 3, in the state in which the support rings 1 and 2 abut, the two switching elements 4 and 10 lie directly next to each other in the circumferential direction, in a common plane running parallel to the separating plane of the support rings 1 and 2.

In addition, FIG. 3 shows a circular housing 20 having the shape of a disc and, together with the base housing 21, in the assembled state forming a bearing housing 22 in which the two bearing rings 1 and 2 are received. the cover 20 is provided on its underside 23 with an annular groove 24 into which the first support ring 1 is fully inserted. The annular groove 24 is concentric with respect to the housing 20.

In the region of its circumferential outer edge 25, the cover 20 is provided vertically downwardly to the first support ring 1 facing the orbital wall 26 which, when assembled, extends into both V-shaped stirrups 7 and 12 of both switching arms 5 and 11 respectively. 27 of the orbital wall 26, a plurality of guide bridges 28 are identical in design and have an approximately arcuate outer surface 29. The number of guide bridges 28 corresponds to the total number of switching elements 4 and 10 which, as mentioned above in FIG. 2, are uniformly arranged on the circumference. These switching elements 4 and 10 are provided with a bearing nose 30 or 31, the width of which corresponds to the spacing of two adjacent guide bridges 28, so that in the assembled state the switching elements 4 and 10 bear with their bearing nose 30 and 31 into their circumferential position between two adjacent guide bridges. 28.

A contact element 32 is arranged between two adjacent guide bridges 28, by which the respective switching element 4, 10, with its contact nose 30, 31, is held in one of its switching positions. For moving the switching elements 4, 10, and their bearing noses 30, 31 to the bearing

298083 B6 elements 32 serve to provide a flexible support bracket 7, 12. By means of this support bracket 7, 12, each of the switching elements 4, 10 can be flexibly deflected in the radial direction in the outward direction so that the switching element 4, 10 The upper switching position to the lower switching position can be moved to abut the associated bearing element 32 and can be maintained in the newly set switching position.

As further evident from FIG. 3, the base sleeve 21 is provided on its outer periphery with a cylindrical orbital outer wall 35, which is provided at its lower end with a toothing 36 for driving the base sleeve 21. In the illustrated embodiment, the substantially horizontal divider 39 at its outer orbital end is provided with an upwardly facing recess 40 of approximately U-shaped shape, into which the when assembled, the load-bearing stirrups 7.12 are adjustable.

In order to connect the housing 20 to the base housing 21, hook-like fastening segments 41 are provided on the underside 23 of the housing 20 of the illustrated embodiment, which can be inserted into corresponding recesses 42 of the base housing 21. For fastening in the recesses 42, these fastening segments 41 are provided. a radially outwardly facing ratchet 43 which, in the assembled state, extends beyond the corresponding, radially outwardly facing shoulder 44 of the associated recess 42.

This ratchet connection of the cover 20 and the base housing 21 reliably ensures simple assembly. In addition, the dimensions in the circumferential direction of the fastening segments 41 and the respective recess 42 are aligned with each other such that the cover 20 is connected in the circumferential direction accurately and in the correct position to the base housing 21 in the mounted state.

In Figures 4 to 7, the housing 20 and the base housing 21 are shown in a top and cross-sectional view. As can be seen from FIG. 4, the round face 49 of the housing 20 can be provided with a 24-hour clock scale on which both the desired switching times can be set and the exact switching time can be read off. Instead of such a 24-hour division, for example, a 7-day dial distribution or other division depending on the desired use of the timer may also be provided on the clock.

It is further clear from FIG. 4 that the guide bridges 28 are uniformly arranged on the circumference and also have the same width or radial depth. Between the guide bridges 28 there are abutment elements 32 to which the aforementioned respective switching elements 4, 10 with abutment noses 30, 3L are assigned. The circumferential width of the grooves 45 between the guide bridges 28 approximately corresponds to the thickness of radially inwardly abutting abutments 30, 3}. these bearing noses 30 and 31 fit radially and axially almost free of play between two adjacent guide bridges 28.

As can be seen from the combination of the views of FIGS. 4 and 5, the apparatus is provided with four fastening segments 41 in which, in section along VV in FIG. 4, the fastening segment 41 (not shown) is the same as the right fastening segment 41 shown in FIG. Further, an annular groove 24 in the lower side 23 of the housing 20 is evident. It is also apparent from Fig. 5 that the housing 20 has the shape of a disc plate and has a cylindrical central opening 46. This cylindrical central opening 46 serves corresponding to the bearing cylinder 47 which extends upwardly of the partition wall 39 of the base housing 21 (FIG. 7). Also, the outer dimensions of the accommodation cylinder 47 correspond to the diameter of the cylindrical central opening 46 of the housing 20.

It is also apparent from Figures 6 and 7 that the base sleeve is provided with a total of four recesses 42, the right recess 42 in Figure 7 being identical to the fourth recess, not shown in Figure 6, since a section along line VII-VII is selected here. The recesses 42 are also uniformly distributed over the circumference, their dimensions being aligned with the dimensions of the fastening segments 41 of the housing 20 such that

When assembled, the fastening segments 41 fit precisely into the respective recesses of the base housing 21, whereby the cover 20 is precisely aligned, especially in the circumferential direction with respect to the base housing 21. 6 and 7 also show a toothing 36 which is located in the region of the lower end portion of the orbital outer wall 35 of the base housing 21. At this point, it should also be noted that the outer surface of the housing 48 of this outer wall 35 It is also provided with a time dial according to the clock dial of FIG. 4. This dial is not explicitly shown in the drawing, but corresponds to the dial on the cover 20 shown in FIG. 4. This clock dial on the housing surface 48 represents the main dial to set the program. and clock time. By means of the dial on the cover 20, the time setting can be read and checked both on the periphery of the cylinder 50 (Fig. 8,9) and on the front, especially when the timer is removed, without having to turn the cylinder 50 to a certain position in order to subtract the relevant data from the dial on the housing.

FIGS. 8 and 9 show a switch cylinder 50 consisting of a housing 20, a base housing 21, an upper support ring 1 and a lower support ring 2 with support switching arms 5, 11, and switching elements 4, 10, which they are connected to them by means of respective support brackets 7, 12.

In the left half of FIG. 8, the switching elements 4 and 10 are shown in an identical upper switching position, in which the bearing lugs 30, 31 abut the associated bearing elements 32. As is apparent from FIG. 4 and 10, the switching arms 5 and 11 diverg from each other in the radially outer region of their outer end portions 6 and 1.3 relative to one another in the direction of the axis of rotation 51 of the switching cylinder 50.

In the right half of FIG. 8, the two switching elements 4 and 10 are shown in an identical lower switching position in which, with their bearing noses 30 and 31, they rest against the lower portion of the bearing element 32.1. the rings 1 and 2 diverg from each other so that they have an axial distance from one another in the direction of the axis of rotation 30 of the switching cylinder 50 with their radially outer end portions 6 and 13. This axial distance, in the two switching positions shown in FIG. 8, as a result of the diverging switching arms 5 and 11, is designed so that the two switching arms 5 and 11 cannot interfere with each other even in the opposite switching position of the switching elements 4 and 10. .

This is particularly important because the switching arms 5 and 11 overlap at least partially in the circumferential direction with respect to the support rings i and 2 in the circumferential direction, as already explained in FIG. 2. At this point, it should be noted that The switching elements 4 are not shown in FIG. 8, since these switching elements 4 are located immediately after the second switching elements 10 of the second support ring 2.

In Fig. 9, the switching elements 4 and 10 are also shown in different switching positions. Thus, on the left side, it is apparent that the second switching element 10 is in the upper switching position as already shown in FIG. 8. As a result, the second switching element 10 with its bearing nose 31 abuts the upper portion of the bearing element 32 of the housing 20. On the other hand, the first switching element 4 is shown in the lower switching position 45 so that its bearing nose 30 (shown in broken lines) abuts the lower part of the respective bearing element 32, which is not clearly visible in FIG. Obviously, in these different switching positions, the carrier stirrups 7 and 12 are located one after the other in the circumferential direction. On the other hand, the two switching arms 5 and 11 in the region of the radially outwardly extending end portions 6 and 13 continue to have an axial spacing relative to one another in the direction of the axis of rotation of the switching cylinder, even if the spacing is only small.

Thus, even with different switching positions of the switching elements 10 and 4, as shown in the left half of FIG. 9, the two switching arms 5 and 11 cannot interfere with each other. It is also not possible for the switching process to be obstructed by the support stirrups 7 and 12, since they lie in the peripheral

The side-by-side and circumferential directions also have at least a minimum distance from each other, as shown in FIG. 2.

In the right half of FIG. 9 the switching elements 4 and 10 are shown in the opposite switching position to the left part of the figure. The first switching element 4 is here in the upper switching position in which its bearing nose 30 (shown in dashed lines) seating element 32, which is not visible in the figure. In contrast, the second switching element 10 occupies a lower switching position and by its bearing nose 31 abuts the lower part of the respective bearing element 32. In this second method of switching two adjacent switching elements 4 and 10, the divergence angle between the two switching arms 5 and 11 is greater than 9 and also greater than the two switching positions shown in FIG. 8. As a result of this arrangement, the two end portions 6 and 13 of the two switching arms 5 and 11 are also switched when switching elements 4 and 10 to the switching position according to FIG. the right halves of FIG. 9 cannot interfere. It is also excluded that the support brackets 7 and 12 interfere with each other in this switching position, as, as explained in the description of the left part of the figure, these brackets 7 and 12 lie in the circumferential direction one behind the other and have a circumferential distance therebetween. quite small.

FIG. 10 shows another exemplary embodiment of a switching cylinder 50/1, which also consists of a bearing housing 22/1, a housing 20/1 and a basic housing 21/1.

In contrast to the embodiment shown in FIGS. 1 to 9, on both support rings 1 and 2, the respective switching elements 10 and 4 are designed as axially offset in the region of the raceway bridge 8.14. It can also be seen from FIG. 10 that the respective switching arms 5/1 and 11/1, also in the opposite switching position of their respective switching elements 10 and 4, cannot interfere with each other since they have a 50/1 rotation of the switching cylinder 50/1 in each switching position on the outer end portions 6/1, 13/1, the distance between them. It can also be seen from FIGS. 8, 9 and 10 that the cover 20 and 20/1, respectively, are fastened in their respective recesses 42, 42/1 by their fastening segments 41, 41/1. Furthermore, it is evident from the figures that for concentric seating, the cover 20, 20/1, with its cylindrical central bore 46,46 / 1 is flush with the bearing cylinder 47.47 / 1.

The embodiment according to the invention, in particular the group connection of the switching elements 4 and 10 to the two separate support rings 1 and 2, constituting the switching ring 3 in the assembled state, allows a plurality of switching elements to be pivotably arranged on the switching cylinder. Due to the constant axial spacing of the outer end portions 6 and 13, respectively 6/1 and 13/1 of the switching arms 5 and,, respectively 5/1 and 11/1, assigned to the support brackets 7 and 12, respectively 7/1 and 12 / 1, the switching arms 5, 11 and 5/1, 11/1 can also have a sufficient circumferential width in the radially inner region relative to the respective support rings 1 and 2, while ensuring high stability of the switching arms 5, 11 In this case, the switching arms 5 and 11, respectively 5/1 and 11/1 can overlap in this radially inner region at least in part without having the switching process of the switching elements 4, W would be limited.

Claims (9)

PATENT CLAIMS A clock with a rotatably driven switching cylinder (50) having a plurality of switching elements (4, 10) arranged on a circular path, which are adjustable to at least two possible switching positions for controlling the switching process and which are radially arranged switching positions of the arms (5, 5/1, 11, 11/1) connected to the switching ring (1, 2, 3) lying 1.0 radially within the annular path of the switching elements (4, 10), wherein the switching arms (5, 5/1, 11, 11/1), when adjusting the switching elements (4, 10), perform a pivotal movement about a rotational axis running substantially tangential to a switching ring (1, 2, 3), and wherein the switching ring (3) consists of two separate carrier rings (1, 2) and the switching elements (4, 10) are divided in equal numbers into a first group (4) connected to the first a carrier ring (1) and a second group 15 (10) connected to a second carrier ring (2), characterized in that the switching arms (5, 5/1) of the first group of switching elements (4) and the switching the arms (11, 11/1) of the second group of switching elements (10), the supporting rings (1, 2) forming the switching ring (3) lying on top of each other, and the first and second switching alternately lying side by side elements (4 and 10) lie on their entire ra the axial spacing of the switching cylinder (50) 20, and at least in the outer radial region of the switching elements (4, 10), have an axial spacing relative to each other, which is dimensioned such that the switching arms (5, 5) / 1 and 11, 11/1) of the first group of switching elements (4) and the second group of switching elements (10), when switching to one of their switching positions, cannot limit each other even if the switching arms (5, 5/1, and 1) overlap partially; 11, 11/1.) In the circumferential direction. A time switch according to claim 1, characterized in that the switching arms (5, 5/1 and 11, 11/1) of the first group of switching elements (4) and the second group of switching elements (10) are circumferential direction away from the switching ring ( 3) radially diverging. 30 A timer as claimed in claim 1 or 2, characterized in that the switching elements with radially outer end portions (6, 6/1, 13, 13/1) of the switching arms (5, 5/1, 11) are provided. , 11/1) are connected by a V-shaped support brackets (7, 7 / 1,12,12 / 1) lying adjacent to one another in the circumferential direction, and that the switching elements (4, 10) are each provided with a radially inwardly facing bearing nose ( 30, 31), by means of which the switching elements (4, 10) are held in a given switching position on the bearing 35 of the switching cylinder (50, 50/1). 4. The timer according to claim 3, characterized in that the switching arms (5, 5 / 1.11, 11/1) and the stirrups (7, 7/1, 12, 12/1) have their radial length in the circumferential direction of substantially constant width. The time switch according to claim 3 or 4, characterized in that the housing (22, 22/1) consists of a housing (20, 20/1) and a basic housing (21, 21/1) such that a plurality of axially extending guide bridges (28) corresponding to the number of switching elements (4, 10) are provided in the housing (20, 20/1) and that guide guides adjoining two circumferentially extending between them A support element (32) is provided with the bridges (28) with which the associated support nose (30, 31) of the switching element (4, 10) can be brought into the form-fit connection in its switching positions. Timer according to claim 5, characterized in that the distance of two adjacent guide bridges (28) approximately corresponds to the circumferential width of the contact nose (30, 31) of the switching switch. 50 of the element (4, 10). -10GB 298083 B6 Timer according to claim 5, characterized in that the first support ring (1) is provided with a raceway first bearing bridge (8) extending towards the housing (20) by which the first support ring (1) abuts in each assembled state each an annular groove (24) of the housing (20), and that A the second support ring (2) is provided with a raceway (14) extending towards the base housing (21), and, when assembled, on the raceway (38). a second support ring (2) abuts the base sleeve (21). Timer according to claim 5, 6 or 7, characterized in that the cover (20, 20/1) in the assembled state is centered and non-rotatably fastened to the base housing (21, 21/1) and by means of locking elements (41) , 42, 43, 44, 41/1, 42/1) is fixed on the base housing (21, 21/1). Timer according to one of Claims 5, 6, 7 or 8, characterized in that a time switch is arranged on the surface of the raceway (48) of the basic housing (21) and on the axial outer face (49) of the housing (20). dial.