DE102015011324B3 - Instant switching date switching mechanism - Google Patents

Abstract

A date switching mechanism (1) comprises a date switching device (2) which can be brought into and out of switching engagement with a date disc (3). First and second positioning wheels (101, 102) are for positioning the date switching means (2). A cam disc (11) is limitedly rotatable relative to the first positioning wheel (101) and rotationally coupled thereto temporarily, and comprises a first and a second peripheral region (121, 122). A sensing finger (14) of the date switching device (2) is in contact with the circumference of the cam disc (11), wherein the date switching means (2) by means of a first link guide (20) on the second positioning wheel (102) is displaceably guided. A spring (30) exerts on the date switching device (2) a spring force, whereby the sensing finger (14) against the circumference of the cam (11) is pressed. The cam plate (11) is designed such that the spring (30) is biased when the sensing finger (14) on the first peripheral portion (121) is applied and relaxed when the sensing finger (14) on the second peripheral portion (122) abuts.

Description

The invention relates to an instant switching date switching mechanism, as it can be used in particular in a mechanical clock, as well as a corresponding clock with such a momentarily switching date switching mechanism.

As a further function of a clock, in addition to the pure time display, often a display of the current date, especially the current day, desired. For this purpose, the mechanical clock comprises a date disc on which the numbers 1 to 31 are applied. This date dial is moved by the movement daily by one division and thus indicates the current date.

The date change can be different depending on the clock. In a "creeping date change" the date disc is moved by means of a cam or a finger, which is firmly engaged with the pointer movement. The actual date change takes place here the slowest and is clearly perceptible.

This is bypassed during the "slow switching date change". The Dateumsradrad is here firmly connected to the pointer movement, the switching finger located thereon, however, is designed resiliently. When the date changes, the shift finger touches the date wheel. The Dateschaltrad moves under this unhindered on and thus spans the date switching spring continues. The date disc is slowly released from the date catch, but is still on this. By the time the force of the strained date spring has become greater than the retention force of the date catch, the date wheel is released abruptly and a tooth pitch is further thrown by the date spring. The date change takes place faster than the "creeping date change", however, the switching time can vary within a certain time window.

In the "instantaneous date switching", a force is slowly built up on the shift finger by means of a special mechanism. Exactly at midnight, the date switching mechanism is released and the date disc is switched within fractions of a second. The date change is completed quickly and the switching time can be precisely defined.

In the DE 1 673 663 C a calendar clock is shown with an adjustment for a date ring. The adjusting device comprises a spring-biased by a spring lever which engages a driven by a drive cam, and an adjusting member for the date ring. The adjusting member is designed as an adjusting lever with a slotted guide into which a stationary pin protrudes. The cam is freely rotatably mounted on the bearing pin of the drive wheel. An attached to the cam and the lever pin protrudes into a slot in the drive wheel. In case of drop of the shift lever, the cam and thus the adjusting lever are rotatable.

From the DE 202 08 525 U1 a clock drive for a mechanical clock is known, which allows an at least largely leaping indexing of the date disc. This is achieved by the fact that the date disc can be indexed by a date drive in the direction of advancement, which can be driven by a spring drive via a gear train.

However, it can be problematic if the date should be corrected manually. This requires a mechanism to move the date wheel from outside the case. Normally, a manually operated crown sets a gear in motion, which moves the date dial in a defined direction (one-sided).

Often, however, exist depending on the caliber so-called blocking periods, ie time windows in which the date may not be corrected manually. This is due to the fact that in these periods the Dateschaltrad is in engagement with the date disc to prepare for the next date change.

If the date is still corrected manually during this period, there is a risk of permanent damage to the date switching mechanism, depending on the design. The damage may extend to the time shift of the date switching time to the total failure of the date function.

It is therefore the object of the invention to provide a date switching mechanism for a clock which, on the one hand, advances the data in fractions of a second at midnight, yet on the other hand permits manual adjustment in both directions outside the very short switching time by means of manual date quick correction. Furthermore, a clock is to be created, which has such a date switching mechanism.

This object is achieved by a date switching mechanism according to claim 1 and by a clock with such a date switching mechanism according to claim 19. Advantageous embodiments of the invention are specified in the subclaims.

The date switching mechanism comprises a date switching device, the one Date release lever and a date shift lever, wherein the date shift lever can be brought into and out of switching engagement with a date disc. First and second positioning wheels are for positioning the date trip lever and date shift lever, wherein the first positioning gear is rotationally coupled to the second positioning gear. A cam is used, which is limited rotatable relative to the first positioning and rotationally coupled with this temporarily. A circumference of this cam has a first and a second peripheral region. The date trigger lever includes a sensing finger that is held in contact with the circumference of the cam. The date shift lever is slidably guided by means of a first slotted guide on the second positioning and articulated by means of a hinge connection with the date tripping lever. A spring which applies a spring force to the date switching means is used, whereby the tactile finger is pressed against the circumference of the cam. The first circumferential portion of the cam plate is designed such that it biases the spring when the cam disk is rotated in a specific direction of rotation, in which state the date shift lever is held out of shunting engagement with the date disk. In contrast, the second peripheral portion of the cam plate is formed so as to permit spring-caused movement of the date trigger lever in the date shift direction, whereby the date shift lever is momentarily indexed with the date dial while being moved relative to the second positioner so as to be instantaneous after a date transition is again brought out of disengagement with the date disc. The date shift lever is exclusively out of engagement with the date dial when turning counterclockwise clockwise.

This has the advantage that a date quick correction can be performed at any time in both directions. The automatic switching of the date happens instantly within fractions of a second. Before or after this shift, the date shift lever is always out of engagement with the date disc. This novel functional principle does not create any blackout periods for the wearer of the watch. Manual date correction can be performed even if the hands are turned back past midnight because the shift lever does not engage the date wheel. When turning back the at least one clock hand, the date shift lever is never brought into engagement with the date wheel (even at the time of the date change). There are thus no blocking periods in which the date could not be corrected.

Preferably, the cam is limited rotatably guided relative to the first positioning via a second link guide, which is spaced from the axis of rotation of the cam and / or from the axis of rotation of the first positioning. For this purpose, the second link guide consists of a slot in which a pin is guided stop limited. The slot is arranged either in the cam or in the first positioning wheel. By contrast, the pin is arranged stationarily on the respective other element and is preferably formed integrally therewith. This ensures that the cam relative to the first positioning is limited relative to this rotatable. At the same time, in a different positioning, so arrangement of the pin within the slot a rotary coupling is achieved, which means that the cam moves synchronously to the first positioning.

When the sensing finger, which is preferably integrally connected to the date trigger lever, is in contact with the first peripheral region, the cam is rotationally coupled to the first positioning wheel in the direction of rotation. The pin of the second link guide is in this case at a first end of the slot. In the event that the sensing finger is in contact with the second peripheral region and the date shift lever momentarily engages the date dial in indexing engagement, the pen is closer to a second end of the slot than to the first end of the slot. In this case, the spring can relax, wherein the cam plate is rotated relative to the first positioning, that is pivoted about a first angular range with respect to this. This first angular range is preferably less than 120 °, but greater than 30 °. The date switching device thereby moves, this movement being limited by the first and second slotted guide. It is a translational movement with preferably two degrees of freedom.

In a further exemplary embodiment, a distance between the first circumferential region of the cam disk and the axis of rotation of the cam disk increases at least in sections in the direction of rotation of the cam disk. Thus, the spring, which preferably bears against the date release lever, tension. In this case, the cam is rotationally coupled to the first positioning. As a result, the feeler finger is pressed further in the direction of the spring, whereby it is tensioned. During the transition from the first to the second circumferential region, a force of the spring via the sensing finger, which bears against the second circumferential region, causes the cam disk to rotate relative to the first positioning wheel. The second peripheral region is preferably straight. The distance from the second peripheral region to the axis of rotation is on average less than from the first peripheral area to the axis of rotation.

In another embodiment, the date shift lever is connected to the date trigger lever via the articulation, which is preferably a ball joint. The articulation can be loaded both on train, as well as on pressure. This means that the date switch lever is permanently connected to the date trigger lever.

In another embodiment, the second positioning wheel is mounted closer than the first positioning wheel at the location of the date disk at which the date shift lever engages and disengages therefrom. This allows the date shift lever can be precisely guided in its position by the first link guide, the second link guide on the first positioning ensures the tensioning and relaxing of the spring. Preferably, the first slide guide also consists of a slot in which a further pin is guided limited stop. Preferably, the elongated hole of the first slotted guide is designed bent, wherein the two ends of the oblong hole are arranged closer to the date disc, as a region between the two ends, that is, a region which is preferably in the middle of the oblong hole. The movement of the date trigger lever in the date shift direction caused by the spring force in this case causes movement of the date shift lever, so that the pin of the slot of the first slide guide moves from the first end towards the second end, wherein the date shift lever is brought into sliding engagement with the date disc when the pin is between both ends, preferably in the middle of the slot. If the pin is nearer one end than in the middle of the slot, then the date shift lever is pivoted out of disengaging engagement with the date wheel. This ensures that the date shift lever can be brought into sliding engagement with the date disc and he can push them to a position, so a catch further to immediately leave the switching engagement position again.

The term "wheel" is preferably understood to mean a "gear". The first and second positioning wheels are therefore gears, which are preferably engaged with each other and therefore rotate in opposite directions. The first positioning wheel can be driven either "indirectly" or "directly" by an hour wheel. In an "immediate" drive, the first positioning wheel is engaged with the hour wheel. Both wheels are touching. In the case of an "indirect" drive, one or more further toothed wheels, such as, for example, a reduction wheel, may be connected between the first positioning wheel and the hour wheel, that is, arranged.

Various embodiments of the invention will now be described by way of example with reference to the drawings. Same objects have the same reference numerals. The corresponding figures of the drawings show in detail:

1 : An illustration of the date switching mechanism according to the invention with a date switching device which is not in sliding engagement with the date disc;

2A . 2 B Fig. 5 shows various representations of the date switching mechanism according to the invention comprising a date switching means which moves in the direction of the switching engagement with the date dial;

3A . 3B Fig. 5 shows various representations of the date switching mechanism according to the invention comprising a date switching means in switching engagement with the date dial; and

4 : An illustration of the date switching mechanism according to the invention, comprising a date switching device which has moved out of the switching engagement with the date disc.

1 shows an illustration of a date switching mechanism according to the invention 1 , which is a date switching device 2 that is not in contact with the date disc 3 stands. The date switching mechanism 1 is used in mechanical watches, which are preferably driven by a vibrating system. The date switching device 2 includes a date trigger 4 and a date shift lever 5 , The date shift lever 5 is, as will be explained later, in and out of engagement with the date wheel 3 brought. The date shift lever 5 and the date trigger 4 are via a hinge connection 6 hinged together. This joint 6 can be loaded on both pressure and tension.

The date switching mechanism 1 gets its power from a gear train, more precisely the minute tube, which is a change wheel 7 and therefore an hour wheel 8th and this in turn a reduction wheel 9 drives.

The date switching mechanism 1 also has a first and a second positioning wheel 10 ₁ , 10 ₂ , used to position the date trigger lever 4 and the date shift lever 5 serve. The first positioning wheel 10 ₁ is with the second positioning 10 ₂ rotationally coupled. A rotation of the first positioning wheel 10 ₁ therefore causes a Rotation, preferably in the opposite direction, of the second positioning wheel 10 ₂ .

The date switching mechanism 1 also includes a cam 11 relative to the first positioning wheel 10 ₁ limited rotation and is rotationally coupled with this temporarily. The cam 11 Also includes a periphery, that is, a side peripheral surface, preferably in a first and a second peripheral region 12 ₁ , 12 ₂ divides. The first peripheral area 12 ₁ is preferably longer than the second peripheral region 12 ₂ . The first peripheral area 12 ₁ may be more than one and a half times as long, more preferably more than twice as long, more preferably more than three times as long as the second peripheral region 12 ₂ . The first peripheral area 12 ₁ is also at least partially, preferably completely bent. In contrast, the second peripheral area 12 ₂ preferably straight. The second peripheral area 12 ₂ can at the transition to the first peripheral area 12 ₁ in the direction of rotation of the cam 11 also have a recess which is designed such that the distance of the second peripheral region 12 ₂ at this indentation a smaller distance from the axis of rotation 13 the cam 11 has, as the first peripheral area 12 ₁ at the transition to the second peripheral region 12 ₂ .

A distance of the first peripheral region 12 _{1 of} the cam 11 towards the axis of rotation 13 the cam 11 takes in the direction of rotation of the cam 11 at least in sections. The direction of rotation of the cam 11 and the direction of rotation of the first and second positioning wheels 10 ₁ , 10 ₂ are indicated by an arrow. This is the primary direction of rotation of the first and second positioning wheels 10 ₁ , 10 _{2 of} the date switching mechanism 1 if it is installed in a clock. The clock hands then turn clockwise. If the clock hands are turned back counterclockwise by means of a crown, the first and second positioning wheels rotate 10 ₁ , 10 ₂ and thus also the cam 11 the other way round.

The cam 11 is preferably on one side of the first positioning wheel 10 ₁ arranged. The rotation axis 13 the cam 11 preferably coincides with the axis of rotation 13 of the first positioning wheel 10 ₁ together.

The cam 11 is, as will be explained later, relative to the first positioning 10 ₁ limited rotatable and rotationally coupled with this second.

The date trigger 4 includes a tactile finger 14 which is in contact with the circumference, ie with the first or second peripheral area 12 ₁ , 12 _{2 of} the cam 11 is held. This tactile finger 14 is preferably constantly in contact with the cam 11 , This means that the touch finger 14 the cam 11 both touched when the date lever 5 in mesh with the date wheel 3 stands, as well as when the date lever 5 except switching engagement with the date wheel 3 stands. When turning back the clock hands (they move counterclockwise), so if the first and the second positioning wheel 10 ₁ , 10 ₂ are rotated counter to the primary direction of rotation, the sensing finger is located 14 not on the cam 11 at.

The date trigger 4 has a shape that approximates an "E". The tactile finger 14 branches in this case from the hull 15 of the date trigger lever 4 in the middle. Distanced from the touch finger 14 includes the date trigger 4 still a first attachment arm 16 , at the end of which the date release lever 4 is pivotally mounted. A second attachment arm 17 is at its end over the articulation 6 with the date shift lever 5 articulated. Both, the first and the second attachment arm 16 . 17 , are in different places with the hull 15 of the date trigger lever 4 connected and run in the same direction.

The date trigger 4 is with his trunk 15 , his finger 14 , his first attachment arm 16 and its second attachment arm 17 preferably formed in one piece. He can therefore around the pivot axis 18 , which are at the end of the first bracket 16 is to be pivoted.

The tactile finger 14 tapers towards the end, which is in contact with the cam 11 stands. The tactile finger 14 can also easily, preferably in sections, in the direction of the pivot axis 18 be bent.

The pivot axis 18 of the date trigger lever 4 is from the touch finger 14 and from the articulation 6 spaced.

The end of the second attachment arm 17 which part of the articulation 6 is larger in diameter than the hull 15 and / or the tactile finger 14 or the first attachment arm 16 ,

At the joint connection 6 it is preferably a ball joint.

The date shift lever 5 is preferably located on a side surface of the second positioning wheel 10 ₂ on. The date shift lever 5 is by means of a first slotted guide 20 on the second positioning wheel 10 ₂ slidably guided. The first slide tour 20 preferably consists of a slot 21 in which a pen 22 limited stop. The slot 21 encloses the pen 22 such that this always within the slot 21 located. The slot 21 the first slide tour 20 is executed at least partially bent. This means that two ends of the slot 21 the first slide tour 20 closer to the date wheel 3 are arranged as a region of the slot 21 extending between both ends, preferably in the middle of the slot 21 located. As a result, as explained in detail later, achieved that the date shift lever 5 very fast in and out of date with the date wheel 3 can be brought.

The slot 21 the first slide tour 20 is in this embodiment in the date shift lever 5 educated. The pencil 22 the first slide tour 20 is fixed, and preferably in one piece on the second positioning wheel 10 ₂ trained. The reverse case, however, would also be conceivable, so that the slot 21 the first slide tour 20 on the second positioning wheel 10 _{2 is} formed, wherein the pin 22 the first slide tour 20 fixed, preferably in one piece to the date shift lever 5 is trained.

The pencil 22 the first slide tour 20 is from the rotation axis of the second positioning wheel 10 ₂ spaced. This preferably also applies to the first link guide 20 and thus for the slot 21 ,

The date shift lever 5 tapers towards the end, which is the hinge joint 6 is furthest apart.

The cam 11 is about a second link guide 25 that of axis of rotation 13 the cam 11 and / or from the axis of rotation 13 of the positioning wheel 10 ₁ is limited, rotatably limited relative to the first positioning 10 ₁ led. The second slide tour 25 also consists of a slot 26 in which a pen 27 limited stop. The slot 26 the second slide tour 25 is bent. A bending radius of the slot 26 is preferably at a bending radius of the peripheral region 12 ₁ adjusted. The slot 26 does not extend along the entire first peripheral area 12 ₁ , but preferably less than 70% of the length of the first peripheral region 12 ₁ , more preferably less than 60% of the length, more preferably less than 50% of the length, more preferably less than 40% of the length. The slot 26 the second slide tour 25 is closer to the first peripheral area 12 ₁ , than at the second peripheral area 12 ₂ .

The slot 26 the second slide tour 25 is in the cam 11 formed, with the pin 27 the second slide tour 25 firmly with the first positioning wheel 10 _{1 is} connected. The pencil 27 and the first positioning wheel 10 ₁ are preferably formed in one piece. A rotation of the first positioning wheel 10 _{1 also} causes movement of the pen 27 , However, it would also be possible for the slot 26 in the first positioning wheel 10 _{1 is} formed and that the pin 27 firmly with the cam 11 connected is. The pencil 27 , is like the slot 26 and thus the second slide guide 25 from the axis of rotation 13 the cam 11 and the first positioning wheel 10 ₁ spaced.

As will be explained later, the pen is located 27 the first slide tour 25 at a first end of the slot 26 when the touch finger 14 in contact with the first peripheral area 12 ₁ stands. In this case, the cam is 11 in the direction of rotation with the first positioning wheel 10 ₁ rotationally coupled.

As will also be explained later, is the pen 27 the second slide tour 25 closer to a second end of the slot 26 than at the first end of the slot 26 when the date shifter 5 briefly with the date disc 3 is brought into switching engagement. In this case, the cam is 11 relative to the first positioning wheel 10 ₁ twisted.

This is a spring 30 needed on the date switch 2 exerts a spring force, whereby the sensing finger 14 against the circumference of the cam 11 is pressed. At the spring 30 it is preferably a leg spring, wherein a first leg fixed to a part of the clock, or at a part of the date switching mechanism 1 supports and is arranged stationary. A second leg of the spring 30 is preferably on the date release lever 4 at. The feather 30 will be curious if the cam 11 is rotated in the primary direction of rotation. In this case, the cam is 11 with the first positioning wheel 10 ₁ rotationally coupled. The tactile finger 14 In this case, it moves along the first peripheral area 12 ₁ . Due to the fact that the distance of the first peripheral area 12 ₁ towards the axis of rotation 13 the cam 11 Enlarged in the direction of rotation, thereby pivoting the date switching device 2 around the pivot axis 18 of the first attachment arm 16 in the direction of the spring 30 triggered. This will be the spring 30 which is on the side of the fuselage 15 of the date trigger lever 4 is applied by the sensing finger 14 spaced apart, compressed. The feather 30 is preloaded. Preloading the spring 30 takes several hours. The tactile finger 14 preferably moves longer than 10 hours, more preferably longer than 12 Hours, more preferably more than 14 hours, more preferably more than 16 hours, more preferably more than 18 hours, but preferably less than 23 hours along the first peripheral region 12 ₁ . The cam 11 is on one side of the first positioning wheel 10 ₁ arranged.

The second positioning wheel 10 ₂ is closer to the place of the date disc 3 attached to the date shift lever 5 in and out of shifting engagement with this, as the first Positionierrad 10 ₁ . Both positioning wheels 10 ₁ , 10 ₂ are preferably the same size, so that one revolution of the first positioning 10 ₁ exactly one revolution of the second positioning wheel 10 ₂ results. The first positioning wheel 10 _{However, 1} could also be smaller or larger than the second positioning wheel 10 ₂ .

The first and the second positioning wheel 10 ₁ , 10 ₂ are preferably smaller than the hour wheel 8th and preferably also smaller than the change wheel 7 , The first and the second positioning wheel 10 ₁ , 10 ₂ could be bigger, though. The same applies to a comparison of the first and second positioning 10 ₁ , 10 ₂ with the reduction wheel 9 ,

The 2A and 2 B show the various representations of the date switching mechanism according to the invention 1 , wherein the date switching device 2 in the direction of a shift engagement with the date wheel 3 emotional. Within the 2A and 2 B is the cam 11 rotationally coupled with the first positioning wheel 10 ₁ . This means that the pen 27 the second slide tour 25 at the first end of the slot 26 the second slide tour 25 is arranged. The cam 11 therefore rotates synchronously with the first positioning wheel 10 ₁ because of the first positioning wheel 10 ₁ fixed pin 27 is taken. The tactile finger 14 therefore moves along the first peripheral area 12 _{1 of} the cam 11 , Within 2 B is the tactile finger 14 at the transition between the first and the second peripheral region 12 ₁ , 12 ₂ . The feather 30 is most excited at this point.

The pencil 22 the first slide tour 20 is near the first end of the slot 21 , The pencil 22 is located on the left half of the second positioning wheel 10 ₂ . Below the "left half" is half of the second positioning wheel 10 ₂ to understand which the positioning wheel 10 ₂ cuts vertically in plan view and closer to the date disc 3 is arranged as the right half. Due to the fact that the pin 22 the first slide tour 20 rotatably on the second positioning 10 _{2 is} arranged in the in 2A and 2 B state shown pivoting the date selector lever relative to the date trigger lever 4 by means of the articulated connection 6 in the direction of the shift engagement point within the date wheel 3 , The date disc 3 includes engagement points in the embodiments 32 which are arranged on their inside. At these intervention points 32 they are preferably spikes, which are further preferably designed trapezoidal. Despite that within 2 B the feather 30 is most excited and a transfer of the date is imminent, is the date shift lever 5 yet out of engagement with the date disc 3 , The date disc 3 Could still be manually adjusted back and forth without the inventive date switching mechanism 1 would be damaged.

The 3A and 3B show various representations of the date switching mechanism according to the invention 1 , wherein the date switching device 2 in mesh with the date wheel 3 stands. The tactile finger 14 is in contact with the second peripheral area 12 _{2 of} the cam 11 , The second peripheral area 12 _{2 of} the cam 11 is formed to have a movement of the date trigger lever caused by the spring force 4 in the date switching direction, allowing the date lever 5 briefly with the date disc 3 brought into switching engagement while relative to the second positioning wheel 10 _{2 is moved} so that it again after a Dateumweiterschaltung except switching engagement with the date disc 3 is brought. By the term "short-term" is meant that the date lever 5 just as long with the date disc 3 in mesh, like the spring 30 needed to move from the tensioned state to the relaxed state. This time lasts less than one second, preferably less than 800 ms, more preferably less than 600 ms, more preferably less than 500 ms, more preferably less than 400 ms, more preferably less than 300 ms.

The cam 11 is over the slot 26 at a certain angle loose with the first positioning wheel 10 ₁ connected. This means that by the force of the spring 30 the date trigger 4 the cam 11 drives, which is due to the long hole 26 by a predetermined angular amount on the first positioning wheel 10 _{1 can} turn.

This means that the pen 27 the second link guide closer to the second end of the slot 26 located as at the first end of the slot 26 ,

At the same time, the movement of the date trigger lever caused by the spring force causes 4 in Dateschaltrichtung a movement of the date switching lever 5 so the pen 22 the first slide tour 20 from the first end to the second end of the slot 21 walks, with the date shift lever 5 in mesh with the date wheel 3 is brought when the pin 22 the first slide tour 20 between both ends, preferably in the middle of the slot 21 like this in the 3A and 3B is shown.

Within 3A is the date shift lever 5 just in contact with the date disk 3 , whereby the date has not yet been updated by one day. This is only within 3B happens.

The moment in which the date lever 5 in mesh with the date wheel 3 is brought, is the cam 11 not with the first positioning wheel 10 ₁ rotationally coupled. The cam 11 is due to the long hole 26 the second slide tour 25 limited to the first positioning 10 ₁ twisted.

Due to the fact that the area of the curved slot 21 the first slide tour 20 extending between the two ends of the slot 21 is, further from the date disk 3 is removed, as the two ends of the slot 21 , the date lever changes 5 while relaxing the spring 30 in the direction of the date disk 3 pressed as soon as the pen 22 goes through this area in the middle.

4 shows a representation of the date switching mechanism according to the invention 1 , wherein the date switching device 2 straight from the switching engagement with the date disc 3 moved out. The feather 30 is completely relaxed at this time. The cam 11 is not at this time with the first positioning wheel 10 ₁ rotationally coupled. The pencil 27 the second slide tour 25 is not stop limited at the first end of the slot 26 the second slide tour 25 arranged. Instead, it is closer to the second end of the slot 26 than at the first end of the slot 26 , The tactile finger 14 migrates along the second peripheral region 12 ₂ and is closer to the axis of rotation 13 the cam 11 , or closer to the axis of rotation 13 of the first positioning wheel 10 ₁ , when he was at the time when he was in contact with the first peripheral area 12 _{1 has} stood.

The pencil 22 the first slide tour 20 is also closer to the second end of the slot 21 the first slide tour 20 than at the second end of the slot 21 ,

Another rotary motion of the second positioning wheel 10 ₂ causes the pen 22 , which rotatably with the second positioning 10 _{2 is} connected, in the direction of the first Positionierrads 10 ₁ moves, causing the date shift lever 5 even further from the date disk 3 is pivoted away. A manual adjustment of the date is possible again without the date switching mechanism according to the invention 1 would be damaged.

The further the first positioning wheel 10 ₁ rotates, the farther the pen moves 27 the first slide tour 25 on the first end of the slot 26 to. Once again he engages the first end of the slot 26 is, is the cam 11 again with the first positioning wheel 10 ₁ rotationally coupled. The tactile finger 14 then moves again from the second peripheral area 12 ₂ in the direction of the first peripheral region 12 ₁ . As soon as he reaches the first perimeter area 12 ₁ contacted again, the game starts again.

The date switching mechanism 1 is used in a clock. Such a clock is preferably designed as a pocket watch or wristwatch. The date switching mechanism 1 is part of a preferably purely mechanical movement, which is preferably driven by a vibrating system.

The invention is not limited to the described embodiments. In the context of the invention, all described and / or drawn features can be combined with each other as desired.

Claims (19)

Date switching mechanism ( 1 ) for a watch with the following characteristics: - a date-switching device ( 2 ), which has a date trigger ( 4 ) and a date shift lever ( 5 ), wherein the date shift lever ( 5 ) in and out of switching engagement with a date disc ( 3 ) can be brought; A first and a second positioning wheel ( 10 ₁ , 10 ₂ ) for positioning the date trigger lever ( 4 ) and date selector lever ( 5 ), wherein the first positioning wheel ( 10 ₁ ) with the second positioning wheel ( 10 ₂ ) is rotationally coupled; - a cam ( 11 ) relative to the first positioning wheel ( 10 ₁ ) is limitedly rotatable and is rotationally coupled therewith at times, and has a circumference comprising a first and a second peripheral region ( 12 ₁ , 12 ₂ ); - the date trigger ( 4 ) comprises a tactile finger ( 14 ) in contact with the circumference of the cam ( 11 ) is held; - the date switch lever ( 5 ) is by means of a first slotted guide ( 20 ) on the second positioning wheel ( 10 ₂ ) slidably guided and is by means of a hinge connection ( 6 ) with the date trigger ( 4 ) hinged; - a spring ( 30 ) referring to the date switching device ( 2 ) exerts a spring force, whereby the sensing finger ( 14 ) against the circumference of the cam ( 11 ) is pressed; - the first peripheral area ( 12 ₁ ) of the cam plate ( 11 ) is designed such that when turning the cam ( 11 ) in a certain direction of rotation the spring ( 30 ), whereby the date shift lever ( 5 ) except switching engagement with the date disc ( 3 ) is held; The second peripheral area ( 12 ₂ ) of the cam plate ( 11 ) is designed such that it causes a movement caused by the spring force of the date trigger lever ( 4 ) in the date shift direction, whereby the date shift lever ( 5 ) briefly with the date disc ( 3 ) and thereby relative to the second Positionierrad ( 10 ₂ ) is moved in such a way that, after a date shift, it is again out of switching engagement with the date disk (FIG. 3 ) is brought; - the date switch lever ( 5 ) is counterclockwise when turning back clockwise exclusively out of engagement with the date disc ( 3 ). Date-shifting mechanism for a timepiece according to claim 1, characterized by the following features: - the cam disc ( 11 ) is via a second link ( 25 ), which depends on the axis of rotation ( 13 ) of the cam and / or of the axis of rotation ( 13 ) of the first positioning wheel ( 10 ₁ ), limited rotatably relative to the first Positionierrad ( 10 ₁ ) guided; - the second slide guide ( 25 ) consists of a slot ( 26 ), in which a pen ( 27 ) is limited stop. Date-shift mechanism for a timepiece according to claim 2, characterized by the following feature: - the oblong hole ( 26 ) of the second slotted guide ( 25 ) is bent. A date changing mechanism for a timepiece according to claim 2 or 3, characterized by the following features: a) the slot (fig. 26 ) of the second slotted guide ( 25 ) is in the cam ( 11 ) and the pen ( 27 ) of the second slotted guide ( 25 ) is fixed to the first positioning wheel ( 10 ₁ ) connected; or b) the slot ( 26 ) of the second slotted guide ( 25 ) is in the first positioning wheel ( 10 ₁ ) and the pen ( 27 ) of the second slotted guide ( 25 ) is fixed to the cam ( 11 ) connected. Clock date switching mechanism according to claim 4, characterized by the following features: - the pen ( 27 ) of the second slotted guide ( 25 ) is located at a first end of the slot ( 26 ), when the touch finger ( 14 ) in contact with the first peripheral region ( 12 ₁ ), whereby the cam disc ( 11 ) rotationally coupled in the direction of rotation with the first positioning wheel ( 10 ₁ ) is; and / or the pen ( 27 ) of the second slotted guide ( 25 ) is closer to a second end of the slot ( 26 ) than at the first end of the slot ( 26 ), when the date shift lever ( 5 ) briefly with the date disc ( 3 ) is brought into switching engagement; and / or - if the date shift lever ( 5 ) briefly with the date disc ( 3 ) is brought into switching engagement, the cam ( 11 ) relative to the first positioning wheel ( 10 ₁ ) twisted. Clock date switching mechanism according to one of the preceding claims, characterized by the following features: - the first peripheral area ( 12 ₁ ) is longer than the second peripheral area ( 12 ₂ ), in particular more than one and a half times as long, more preferably more than twice as long; and / or the first circumference area ( 12 ₁ ) is at least partially, preferably completely bent; and / or the second peripheral region ( 12 ₂ ) is straight. A date switching mechanism for a timepiece according to any one of the preceding claims, characterized by the following feature: a distance of the first peripheral area ( 12 ₁ ) of the cam plate ( 11 ) to the axis of rotation ( 13 ) of the cam ( 11 ) takes in the direction of rotation of the cam ( 11 ) at least in sections. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following features: - the cam disc ( 11 ) is connected to the first positioning wheel ( 10 ₁ ) is rotationally coupled when the sensing finger ( 14 ) in contact with the first peripheral region ( 12 ₁ ) stands; and / or the cam disc ( 11 ) is on one side of the first Positionierrads ( 10 ₁ ) arranged. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following feature: a pivoting axis ( 18 ) of the date trigger lever ( 4 ) is from the feeler finger ( 14 ) and of the articulated connection ( 6 ) spaced. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following features: - the spring ( 30 ) is due to the date trigger ( 4 ) at; and / or - at the spring ( 30 ) is a leg spring. Date-shift mechanism for a timepiece according to one of the preceding claims, characterized by the following feature: - in the articulated connection ( 6 ) is a ball joint, the date shift lever ( 5 ) permanently with the date release lever ( 4 ) connects. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following feature: - the second positioning wheel ( 10 ₂ ) is closer than the first positioning wheel ( 10 ₁ ) in place of the date disc ( 3 ), at which the date shift lever ( 5 ) gets into and out of meshing engagement with this. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following feature: - the first slide guide ( 20 ) consists of a slot ( 21 ), in which a pen ( 22 ) is limited stop. Date-shift mechanism for a timepiece according to claim 13, characterized by the following features: 21 ) of the first slide guide ( 20 ) is executed bent at least in sections; and / or - the slot ( 21 ) of the first slide guide ( 20 ) is in the date shift lever ( 5 ) and the pen is ( 22 ) fixed to the second positioning wheel ( 10 ₂ ) connected; or the slot ( 21 ) of the first slide guide ( 20 ) is in the second positioning wheel ( 10 ₂ ) and the pen ( 22 ) is fixed with the date shift lever ( 5 ) connected Date-shifting mechanism for a timepiece according to claim 14, characterized by the following features: - two ends of the oblong hole ( 21 ) of the first slide guide ( 20 ) are closer to the date wheel ( 3 ), as a region of the slot ( 21 ) extending between both ends, preferably in the middle of the slot ( 21 ) is located; and - the movement of the date trigger lever caused by the spring force ( 4 ) in Dateschaltrichtung causes a movement of the date switching lever ( 5 ), so the pen ( 22 ) of the first slide guide ( 20 ) from the first end to the second end of the slot ( 21 ), whereby the date shift lever ( 5 ) in switching engagement with the date disc ( 3 ) is brought when the pin between both ends, preferably in the middle of the slot ( 21 ) is located. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following features: - the first sliding guide ( 20 ) is spaced from the axis of rotation of the second Positionierrads ( 10 ₂ ) arranged; and / or the date shift lever ( 5 ) lies on a side surface of the second positioning wheel ( 10 ₂ ). Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following features: - the first and the second positioning wheel ( 10 ₁ , 10 ₂ ) rotate in opposite directions; and / or - the first positioning wheel ( 10 ₁ ) is powered by: a) an hour wheel ( 8th ); or b) a reduction wheel ( 9 ), which in turn depends on the hour wheel ( 8th ) is driven. Date-shifting mechanism for a timepiece according to one of the preceding claims, characterized by the following feature: - the tactile finger ( 14 ) and the date trigger ( 4 ) are integrally formed. Clock with a date switching mechanism ( 1 ) according to one of claims 1 to 18.

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