JP6773757B2 - Step drive for watches - Google Patents

Description

The present invention relates to a step drive device for a clock, and in particular, by a movement, one rotation is performed in 10 steps every 10 minutes to rotate and drive the first rotation shaft, and the first rotation shaft is rigidly coupled to the first display member. The first-ranked vehicle and its first-ranked vehicle can be rotationally driven around the ten-position rotating shaft by 10 steps every 10 minutes in the forward direction, and the ten-position display member can be rotated around the first-ranked rotating shaft for one hour. A tenth shift vehicle that rotates and drives only six tenth steps each time, and a time display member that can rotate and drive only one step every hour around the time axis by the first or tenth shift vehicle. With respect to a step drive device comprising.

In such a step drive device, it is known that the display member of the clock is instantaneously rotated at an hour interval. In this case, the energy required to instantaneously rotate the display element every hour is stored by the spring device over the course of one hour. The energy is transferred from the movement to the spring device via the first gear.

An object of the present invention is to support a shift of a tens step in a tens display member by providing a step drive device having a simple configuration for a timepiece of the type described at the beginning, and to support the shift of the tens step in the tens display member. In addition to the tenth step on the tenth display member, the shift of the hour step on the hour display member is also supported.

In order to solve this problem, the step drive device according to the present invention further includes a charge surface that can rotate around the ten-position rotation axis, and the charge surface is coaxially rigidly coupled to the ten-position shift wheel and connected to the ten-position shift vehicle. From the minimum diameter point to the maximum diameter region, it spirally rises in the direction opposite to the forward feed direction over an angle of> 260 ° to <360 °, and the minimum diameter point and the maximum diameter region are opposite to the forward feed direction. It further comprises a shift spring that is connected to each other at a rotation angle of <100 ° in a tens shift vehicle by a downward slope in the direction and abuts directly or indirectly in the radial direction with respect to the charge surface. It can be urged by the rotation of the charge surface during the first 9 steps of the position wheel, and slides inward in the radial direction along the charge surface during the 10th step. It is characterized by that.

The charge surface preferably rises spirally in an angle region of> 324 ° to <360 °, and the minimum and maximum diameter points have a rotation angle of <36 ° due to the slope opposite to the forward feed direction. Are connected to each other.

When shifting the tenth place display member and the hour display member in addition to the first place display member, a larger torque is required to shift all the display members. This larger torque is also supplied during individual shifts in the 1st place display member, which introduces unnecessary energy and therefore requires larger dimensions. If the charge surface is arranged, the excess energy can be used for nine shifts in the first place indicator member to urge the shift spring. When the shift spring is located at the maximum diameter of the charge surface (the first place display member displays the number 9 at this position), the shift spring is in the state immediately before pressing the slope of the charge surface. Here, when the first-position display member starts shifting from 9 to 0, the shift spring moves to the descending slope of the charge surface. As a result, the shift spring starts supporting the shift of the tens position display member, and also supports the shift of the time display member when the time is advanced.

Thanks to this support, it is possible to lower the torque supplied by the movement, and thus its spring housing, to allow the tens and hour display members to shift. The torque required for each shift in the 1st place display member needs to be increased only slightly.

In a simple embodiment, the shift spring is formed as a spring arm in which one end region is fixedly arranged and the other free end region in the spring arm is in direct or indirect contact with the charging surface. ing.

When the shift spring is indirectly brought into contact with the charge surface, the multi-arm type tens shift lever that is rotatably supported around the shift lever axis is loaded by the shift spring in the shift spring arm and the charge arm. It can be brought into contact with the charge surface in the end region of the.

The 1st place display member can be configured as a single digit disc having a number 0-9 in the circumferential direction, and / or the 10th place display member can be configured as a double digit disc having a number 0-5 in the circumferential direction. It can be configured and / or the hour display member can be configured as an hour disk having a number 0-11 or 1-12 in the circumferential direction.

The 1st place display member is configured as a 1st place pointer instead of the 1st place disk, the 10th place display member is configured as a 10th place pointer instead of the 10th place disk, and the hour display member is configured as an hour pointer instead of the hour disk. It may be configured as.

If the rotation axes of the 1st place display member and the 10th place display member are coaxially arranged with each other, the required space can be reduced.

In a simple embodiment, in order to shift the ten-position display member, the ten-position shift finger is rigidly coupled to the ten-position shift vehicle, and the ten-position shift finger has a radial distance from the ten-position rotation axis. It has forward feed pins parallel to the tens rotation axis, and the forward feed pins can engage with a star wheel with six radial slots formed to be evenly distributed on the circumference. As a result, the ten-position display member can be rotationally driven around the first-position rotation axis by six ten-position steps every hour.

When each display member is manually adjustable in both directions with the crown, the swivel lever rotates the 1st, 10th and hourly discs and is parallel to the 10th axis by a manually operable crown axis. It is possible to swivel between the disengagement swivel position and the mesh swivel position around the swivel axis, and the swivel lever does not engage with the swivel arm of the tens shift lever when it is in the mesh swivel position. The tens shift lever can be loaded so as to turn away from the charge surface by moving from the meshing turning position to the leaving turning position by the turning lever.

As a result, when the display member is reset, the swivel lever avoids an undesired collision, particularly a collision with the descending slope of the charge surface.

In this case, in a simple embodiment, the swivel arm has a swivel curved surface, and the swivel nose of the swivel lever slides along the swivel curved surface when swiveling from the meshing swivel position to the disengagement swivel position. If the tens shift lever can be loaded so as to turn away from the charging surface, continuous turning movement is realized.

In order to fix the swivel arm in the disengagement swivel position, in a simple embodiment, when the swivel nose is in the disengagement swivel position of the swivel lever, the display member is modified and the crown shaft returns to its normal position again. Up to, it can be engaged with the engaging recess formed at the end of the swivel curved surface of the swivel arm.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

It is a perspective view which shows the step drive device which includes a display disk. It is explanatory drawing which shows the function-related area of the step drive device in FIG. It is a top view which shows the step drive mechanism in FIG. 1 in the state which includes the 1st place disk and the 10th place disk. It is a top view which shows the step drive mechanism in FIG. 1 at the 1st shift position. It is a top view which shows the step drive mechanism in FIG. 1 at the 2nd shift position. It is a top view which shows the step drive mechanism in FIG. 1 at the 3rd shift position. It is an enlarged view which shows the charge disk of the step drive mechanism in FIG.

The drive shift wheel 1 is coupled to the intermediate wheel 3 having 20 teeth via a shaft 2 so as to be relatively non-rotatable, and is rotated by 72 ° every minute by a step drive mechanism (not shown). As a result, the intermediate wheel 3 rotates by an angle corresponding to four teeth every minute.

The intermediate wheel 3 is engaged to the leading wheel 4 having 40 teeth and therefore rotates by 36 ° every minute. That is, the first-ranked car 4 makes exactly one revolution in 10 minutes.

The first-place wheel 4 is concentrically and non-rotatably connected to the first-place disk 5 having a number from 0 to 9 in the circumferential direction, and is rotatably supported on the tens-position axis 6.

A ten-position disc 8 having a number 0 to 5 in the circumferential direction is arranged on the ten-position axis 6 so as to be relatively non-rotatable.

The first-place wheel 4 is engaged with a ten-position shift wheel 9 having 40 teeth. The tens shift wheel 9 takes exactly 10 steps around the tens rotation shaft 7 in 10 minutes, and rotates over a rotation angle of 36 ° in each step.

The ten-position shift finger 10 is rigidly coupled to the ten-position shift vehicle 9 in the radial direction, and the ten-position shift finger 10 has a radial distance from the ten-position rotation axis 7 and is relative to the ten-position rotation axis 7. It has parallel forward pins 27.

The charge disc 11 is coaxially coupled to the tenth shift vehicle 9 so as not to rotate relative to the tenth shift vehicle 9. The charge disk 11 has a charge surface 12 on its circumferential contour, and the charge surface 12 includes a spiral region 13 extending spirally over an angular range of 335 ° and an inclined descending surface 14. In this case, the inclined descending surface 14 connects the point having the minimum diameter in the radial direction (minimum radial point in the radial direction) 15 and the region having the maximum diameter in the spiral region 13 (maximum diameter region) 16 to each other.

FIG. 7 is an enlarged view of the charge disk 11 having a charge surface.

In the charge disk 11 according to the illustrated embodiment, the charge surface 12 is divided into 10 angular ranges. Of these 10 angular ranges, in the first 9 angular ranges 35 from the radial minimum radial point 15 to the radial maximum radial region 16, the charge surface 12 in the first angular range portion 36 is the tens rotation axis. After extending concentrically with respect to 7, it rises in the second angle range portion 37. As a result, the second angle range portion 37 reaches the next angle range 35 in a state where the diameter is expanded by a specific radial distance 38. The charge surface 12 of the first angle range portion 36'in the angle range 35'of the tenth step also extends concentrically with respect to the tens rotation axis 7, and then extends through the inclined surface 14 to the second angle range. At part 37', it returns to the minimum diameter point 15.

A three-arm type tens shift lever 17 is rotatably supported around a shift lever axis 18 parallel to the tens rotation shaft 7. The tens shift lever 17 is composed of a shift spring arm 19, a charge arm 20, and a swivel arm 21.

The free end region of the shift spring arm 19 allows the free protruding end region of the shift spring 22 configured as the spring arm to be loaded. The other end region of the shift spring 22 is fixedly arranged.

The charge arm 20 has a contact tip portion 23 at its free end, and is in radial contact with the charge surface 12 via the contact tip portion 23 in normal operation of the watch.

The tens shift vehicle 9 and the charge disc 11 connected to the tens shift vehicle 9 are rotationally driven by a step drive mechanism, whereby the charge surface 12 starts from the minimum diameter point 15 and follows the contact tip portion 23. While moving only 9 steps. That is, the first-ranked disc 5 is in the position indicating the number 9 (see FIG. 4).

When the 1st place disc 5 is further shifted to the following 0 in the next 10th step, it is rigidly coupled to the 10th place shift wheel 9 and is evenly arranged on the circumference by the 10th place shift finger 10 oriented in the radial direction. The star wheel 25 having the distributed radial slots 26 rotates further every hour by 6 steps of tens. Further rotation of the star wheel 25 is such that a forward pin 27 having a radial spacing with respect to the tens rotation axis 7 and extending parallel to the tens rotation axis 7 engages one of the radial slots 26. It is caused by doing. Due to the rotation of the star-shaped wheel 25, the ten-position disc 8 firmly connected to the star-shaped wheel 25 also moves further by one step of the ten-position step.

If the 1st and 10th discs show exactly 59 minutes, the next step shift in the 1st disc 5 will cause the hour disc (not shown) to move further.

While the charging surface moves in the first nine steps, the contact tip 23 moves radially outwards, and the tens shift lever 17 moves the shift spring 22 through the shift spring arm 19. Turn to be urged at the step of walking.

In the tenth step on the charge surface 12, the contact tip 23 reaches the inclined surface 14 region of the charge surface 12, so that the tens shift lever 17 having the contact tip 23 is under the action of the shift spring 22 force. An additional force is applied to the charge surface 12 and therefore an additional force is also applied to the tenth shift vehicle 9 and the tenth shift finger 10. As a result, the ten-position shift finger 10 further shifts the star-shaped wheel 25 to which the ten-position disc 8 is connected by applying additional torque, and further shifts the hour disc every hour.

The crown shaft 28 can be manually displaced between the normal position and the adjusted position in its longitudinal direction. At the adjustment position of the crown shaft 28, the 1st place disc 5, the 10th place disc 8 and the hour disc can be adjusted in both rotation directions for correction. During the adjustment, the charge disk 11 also rotates. In this case, if rotation occurs in a direction opposite to the normal forward feed direction, the contact tip portion 23 moves slowly on the inclined surface 14 in the radial direction, which may be suppressed in some cases. In order to avoid this, the swivel lever 29 can be swiveled between the disengagement swivel position and the meshing swivel position around the disengagement swivel axis 30 parallel to the tens rotation shaft 7 by the crown shaft 28.

The swivel lever 29 does not engage with the swivel arm 21 of the tens shift lever 17 when it is in its meshing swivel position (see FIGS. 4 and 5).

When the swivel lever 29 is engaged by the crown shaft 28 and swivels from the swivel position to the detached swivel position, the swivel lever 29 abuts on the swivel curved surface 32 of the swivel arm 21 by its swivel nose 31 and follows the swivel curved surface 32 with further swivel. Sliding like. As a result, the swivel lever 29 swivels the swivel arm 21, and therefore the tenth shift lever 17, so that the contact tip portion 23 is separated from the charge surface 12 in the radial direction.

At the position where the contact tip portion 23 is most distant from the charge surface 12, the swivel nose 31 reaches the engaging recess 33 at the end of the swivel curved surface 32 and engages with the engaging recess 33. As a result, the ten-position shift lever 17 and the contact tip portion 23 thereof are fixed at a position separated from the charge surface 12 until the crown shaft 28 is returned to the normal position again (see FIG. 6).

1 drive shift vehicle
2 axes
3 Intermediate car
4 First place car
5 First place disc
6 Ten-position axis
7 Ten-position rotation axis
8 tenth disk
9 10th shift car
10 10th shift finger
11 Charge disc
12 Charge surface
13 Charge disk spiral area
14 Downhill
15 minimum diameter point
16 Maximum diameter area
17 Tenth shift lever
18 Shift lever axis
19 Shift spring arm
20 Charge arm
21 swivel arm
22 shift spring
23 Contact tip
25 star car
26 radial slot
27 Forward pin
28 Crown shaft
29 Swivel lever
30 turning axis
31 swivel nose
32 turning curved surface
33 Engagement recess
34 1st place rotation axis
35 angle range
35'10th step angle range
36 1st angle range part
The first part in the angle range of the 36'10th step
37 Second angle range part
The second part in the angle range of the 37'10th step
38 Radial distance

Claims (9)

It is a step drive device for watches.
・ By the movement, the 1st place rotation shaft (34) is rotationally driven by making one rotation in 10 1st place steps every 10 minutes, and the 1st place wheel (4) rigidly coupled to the 1st place display member.
-The first-ranked wheel (4) is rotationally driven around the ten-position rotating shaft (7) by 10 steps every 10 minutes in the progressive direction, and the ten-position display member is rotated around the tenth-ranked rotating shaft (34). A tenth shift car (9) that rotates and drives only six tenth steps every hour around
-The time display member that is rotationally driven by the first-ranked wheel (4) or the tenth-ranked shift wheel (9) by one step every hour around the time axis.
In a step drive device equipped with
A charge surface (12) that is rotatable around the ten-position rotation axis (7) is further provided, and the charge surface (12) is coaxially rigidly coupled to the ten-position shift wheel (9) and has a> 260 °. Over an angle of ~ <360 °, it spirally rises from the minimum diameter point (15) to the maximum diameter region (16) in the direction opposite to the forward feed direction, and the minimum diameter point (15) and the maximum diameter region (15) 16) are connected to each other at a rotation angle of <100 ° in the tenth shift vehicle (9) by a descending slope (14) opposite to the forward feed direction, and are radially connected to the charge surface (12). The shift spring (22) is further provided with a shift spring (22) that directly or indirectly abuts on the charge surface (12) during the first nine steps of the first place wheel (4). A step drive device that can be urged by the rotation of the wheel and slides inward in the radial direction along the charge surface (12) at the first step of the 10th step. The step drive device according to claim 1, wherein the shift spring (22) is formed as a spring arm in which one end region is fixedly arranged, and the other free end region in the spring arm is charged. A step drive device characterized in direct or indirect contact with a surface (12). The step drive device according to claim 1 or 2, wherein a multi-arm type tens shift lever (17) rotatably supported around a shift lever axis (18) is described in the shift spring arm (19). A step drive device characterized in that it is loaded by a shift spring (22) and is in contact with the charge surface (12) at the end region of the charge arm (20). The step drive device according to claim 3 , wherein the first-position display member is configured as a first-position disk (5) having a number 0 to 9 in the circumferential direction, and / or the ten-position display member is , And / or the time display member is configured as a time disc having a number 0-11 or 1-12 in the circumferential direction, and / or as a tens disk (8) having a number 0-5 in the circumferential direction. A step drive device characterized by being The step drive device according to any one of claims 1 to 4, wherein the rotation axes of the first-position display member and the ten-position display member are coaxially arranged with each other. .. The step drive device according to any one of claims 1 to 5, wherein the ten-position shift finger (10) is rigidly coupled to the ten-position shift vehicle (9), and the ten-position shift finger (10) is rigidly coupled. Has a radial spacing with respect to the ten-position rotation axis (7) and a forward feed pin (27) parallel to the ten-position rotation axis (7), and the forward feed pin (27) is on the circumference. It is engageable with a star wheel (25) having six radial slots (26) formed to be evenly distributed around the ten-position display member around the one-position rotation axis (34). A step drive device characterized in that it can be rotationally driven by 10 steps of 6 steps every hour. The crown shaft according to claim 4 , wherein the swivel lever (29) rotates the first-position disc (5), the ten-position disc (8), and the time disc, and can be manually operated. According to (28), it is possible to swivel between the disengagement swivel position and the meshing swivel position around the swivel axis (30) parallel to the tenth rotation axis (7), and the swivel lever (29) engages with the meshing. When in the swivel position, the tenth shift lever (17) does not engage with the swivel arm (21), and the tenth shift lever (17) engages with the swivel lever (29). A step drive device characterized in that by moving from a position to the detached turning position, a load can be applied so as to turn away from the charge surface (12). The step drive device according to claim 7, wherein the swivel arm (21) has a swivel curved surface (32).
The swivel nose (31) of the swivel lever (29) slides along the swivel curved surface (32) when swiveling from the meshing swivel position to the disengagement swivel position, whereby the tenth shift lever (31) A step drive device characterized in that 17) can be loaded so as to swivel away from the charging surface (12). The step drive device according to claim 8, wherein the swivel nose (31) has a swivel curved surface (32) on the swivel arm (21) when the swivel lever (29) is in the detached swivel position. A step drive device comprising engaging with an engagement recess (33) formed at an end.