JP2003344559A - Self-winding watch with reversing wheel and pinion - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a self-winding watch equipped with a self-winding mechanism including a reversing wheel and pinion in which there is no fear of generating a state where wheels are locke with each other or a state where a driving wheel does not engage with a wheel to be driven and whose transmission efficiency of a rotation can be increased. <P>SOLUTION: The reversing wheel and pinion 220 includes a reversing wheel pinion 222, an upper reversing wheel and pinion 230, an upper support for reversing 236, a reversing lever 238, a lower reversing wheel and pinion 240, and a lower support for reversing 246. The upper reversing wheel and pinion 230 includes an upper reversing wheel gear 232 and an upper reversing pinion 234. The lower reversing wheel and pinion 240 includes a lower reversing wheel gear 242 and a lower reversing pinion 244. An upper operation portion 238b of the reversing lever 238 is engaged with a ratchet wheel 234h of the upper reversing pinion 234, and a lower operation portion 238f is engaged with a ratchet wheel 244h of the lower reversing pinion 244. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic winding timepiece having an automatic winding mechanism including a switching transmission wheel for switching rotation of a rotary weight in two directions to rotation in one direction.

[0002]

2. Description of the Related Art (1) Self-winding wristwatch having two sets of switching mechanism The structure of a conventional self-winding wristwatch having two sets of switching mechanism is as follows.
It is disclosed in Japanese Utility Model Publication No. 47-18706. In the automatic wristwatch disclosed in Japanese Utility Model Publication No. 47-18706, the first switching mechanism and the second switching mechanism mesh with the rotary weight pinion. When the rotary weight rotates in the first direction, the mainspring can be wound up through the rotation of the first switching mechanism, and when the rotary weight rotates in the second direction, the rotation of the second switching mechanism and the transmission wheel is prevented. The mainspring can be wound up through it. In the structure disclosed in Japanese Utility Model Publication No. 47-18706, when the rotary weight rotates in the first direction, the second switching mechanism does not transmit the rotation, and when the rotary weight rotates in the second direction. The second switching mechanism is configured not to transmit rotation. An example of a conventional automatic winding mechanism provided with such two sets of switching mechanisms is "Theoried'horlogerie", pp. 175-180, author: Charles-Reymondin et al., 1
Edition de la Federation des Ecole, October 998
s Techniques (FET), Suisse Reproduction interdite,
Tous droits d'auteurs reserves).

(2) Self-winding watch having one switching transmission wheel Further, referring to FIG. 10, in the conventional automatic winding timepiece having one switching transmission wheel, the automatic winding mechanism has the rotary weight 5
10, the first intermediary vehicle 512 that rotates based on the rotation of the rotary weight 510, the second intermediary vehicle 516 that rotates based on the rotation of the first intermediary vehicle 512, the first intermediary vehicle 512 and the second intermediary vehicle 516. A switching transmission wheel 520 that rotates in one direction based on the rotation of the. The rotary weight 510 has a train wheel bridge 56.
2, the inner ring 510a fixed to 2, and a plurality of balls 510b
An outer ring 510c, a rotary weight pinion 510d integrally provided with the outer ring 510c, a rotary weight body 510e fixed to the outer ring 510c, and a rotary weight 510f fixed to the rotary weight body 510e. The outer ring 510c is configured to be rotatable with respect to the inner ring 510a via balls 510b. The first intermediate vehicle 512 includes a first intermediate gear 512a and a first intermediate pinion 512b. The first intermediary vehicle 512 is the main plate 5
It is provided rotatably with respect to the first intermediary wheel pin 502g provided on 02. The rotary weight pinion 510d most meshes with the intermediate gear 512a. The switching transmission wheel 520 includes a switching transmission pinion 522, an upper switching wheel 530, and a switching transmission pinion 522.
A switching upper seat 536 fixed to the switching transmission pinion 522, a switching intermediate seat 524 fixed to the switching transmission pinion 522, a switching lower stage wheel 540, and a switching lower seat 546 fixed to the switching transmission pinion 522.

The upper switching car 530 is the first intermediary 512.
The switching upper gear body 532 that meshes with b, and the ratchet gear 5
34h and a switching upper ratchet wheel 534 fixed to the switching upper gear body 532. The switching upper gear body 532 and the switching upper ratchet wheel 534 are configured to be rotatable with respect to the switching upper seat 536 between the flange portion of the switching upper seat 536 and the switching middle seat 524. The lower switching vehicle 540 is the second intermediate vehicle 5.
A switching lower gear body 542 that meshes with the 16 second intermediate gear,
A switching lower gear body 542 having a ratchet gear 544h
And a switching lower ratchet wheel 544 fixed to. The switching lower gear body 542 and the switching lower ratchet wheel 544 are provided with the switching lower seat 546.
It is configured to be rotatable with respect to the switching lower seat 546 between the collar portion and the switching middle seat 524. Switch transmission wheel pin 5
26 is fixed to the switching intermediate seat 524. Upper clutch pawl 5
38 is arranged between the switching upper gear body 532 and the switching intermediate seat 524 so that the switching transmission wheel pin 526 can rotate about the rotation center. The upper ratchet pawls 538b and 538c of the upper clutch pawl 538 are configured to be able to mesh with the ratchet gear 534h of the switching upper pawl wheel 534. The lower clutch pawl 548 is rotated about the switching transmission wheel pin 526 so that the switching lower gear body 542 can rotate.
And the switching intermediate seat 524. The lower ratchet pawls 548b and 548c of the lower clutch pawl 548 are configured to be able to mesh with the ratchet gear 544h of the switching lower pawl wheel 544.

Referring to FIG. 11, the operation when the rotary weight 510 rotates in the clockwise direction will be described. When the rotary weight 510 rotates in the clockwise direction, the first intermediary vehicle 51
2 rotates counterclockwise. When the first intermediary wheel 512 rotates counterclockwise, the switching upper gear body 532 rotates clockwise. When the switching upper gear body 532 rotates clockwise, the switching upper ratchet wheel 534 also rotates clockwise. In this state, the upper ratchet pawl 538b meshes with the ratchet gear 534h of the switching upper pawl wheel 534, and the switching intermediate seat 524 rotates clockwise, so that the switching transmission pinion 522 also rotates clockwise. When the first intermediary vehicle 512 rotates counterclockwise, the second intermediary vehicle 516 rotates clockwise. Second intermediary vehicle 51
When 6 rotates in the clockwise direction, the switching lower gear body 542 rotates in the counterclockwise direction. When the switching lower gear body 542 rotates counterclockwise, the switching lower ratchet wheel 544 also rotates counterclockwise. In this state, since the lower ratchet pawls 548b and 548c operate so as to escape from the ratchet gear 544h of the switching lower pawl wheel 544, the switching transmission pinion 522 cannot be rotated by the rotation of the switching lower gear body 542.

Next, referring to FIG. 12, the rotary weight 510
The operation when is rotated counterclockwise will be described. When the rotary weight 510 rotates counterclockwise, the first intermediary wheel 512 rotates clockwise. No.5 intermediary vehicle
When 12 rotates clockwise, the switching upper gear body 532
Rotates counterclockwise. When the switching upper gear body 532 rotates counterclockwise, the switching upper ratchet wheel 534 also rotates counterclockwise. In this state, since the upper ratchet pawls 538b and 538c operate so as to escape from the ratchet gear 534h of the switching upper pawl wheel 534, the switching transmission pinion 522 cannot be rotated by the rotation of the switching upper gear body 532. When the first intermediary vehicle 512 rotates clockwise, the second intermediary vehicle 516 rotates counterclockwise. When the second intermediate wheel 516 rotates counterclockwise, the switching lower gear body 542 rotates clockwise. When the switching lower gear body 542 rotates clockwise,
The switching lower ratchet wheel 544 also rotates clockwise. In this state, the lower ratchet pawl 548b is the switching lower pawl wheel 54
4 ratchet gear 544h meshes with the switching intermediate seat 52
Since 4 rotates in the clockwise direction, the switch transmission pinion 522
Also rotates clockwise. Therefore, in such an automatic winding mechanism, the switching transmission pinion 522 is in a fixed direction, that is, in the clockwise direction, regardless of whether the rotary weight 510 rotates in the clockwise direction or the rotary weight 510 rotates in the counterclockwise direction. Can be rotated.

In this automatic winding mechanism, since the rotation direction of the switching transmission pinion 522 is constant regardless of the direction in which the rotary weight rotates, the first transmission wheel 550 or the like is moved based on the rotation of the switching transmission pinion 522. A square wheel (not shown) can rotate only in one direction through the rotation of the transmission train including the above. Then, by rotating the ratchet wheel, the mainspring in the barrel wheel (not shown) can be wound up in only one direction.

[0008]

(1) Problem of self-winding wristwatch provided with two sets of switching mechanism In the conventional self-winding wristwatch provided with two sets of switching mechanisms, two sets of switching mechanisms are required, and The number of parts that make up the switching mechanism is large, the number of parts manufacturing steps is large, and the assembly steps are large. Further, in the structure of this switching mechanism, the design conditions of the pawl and the cam are very strict, and therefore, there is a possibility that bracing or idling may occur between the pawl and the cam due to variations in manufacturing quality at the time of manufacturing these parts. .

Further, in the structure of the conventional self-winding timepiece having one switching transmission wheel, the design conditions of the ratchet gear of the upper ratchet pawl and the switching upper pawl wheel, the design of the lower ratchet pawl and the ratchet gear of the switching lower pawl car. Since the conditions are very strict, due to variations in the manufacturing quality (dimensions, shapes, etc.) during the manufacturing of these parts, there is a possibility that the upper ratchet pawl and the ratchet gear of the switching upper pawl wheel may be thrust or run out. , There was a possibility that tension or miss could occur between the lower ratchet pawl and the ratchet gear of the switching lower pawl car. (2) Problem of self-winding wristwatch having one switching transmission wheel Further, in the structure of the conventional self-winding wristwatch having one switching transmission wheel, the area occupied by the upper ratchet pawl is large. Since it became smaller and the area occupied by the lower ratchet pawl was large, the switching upper pawl wheel was smaller. For this reason, the number of teeth of the switching upper pawl wheel is reduced, the number of teeth of the switching lower pawl wheel is reduced, and it is difficult to increase the rotation transmission efficiency in the switching transmission wheel. Further, in the structure of the switching transmission vehicle including the conventional switching upper pawl car and the switching lower pawl car, the upper ratchet pawl and the lower ratchet pawl are
It had to be configured as a separate part, with the upper ratchet pawl rotatably assembled to the upper pawl pin and the lower ratchet pawl rotatably assembled to the lower pawl pin. Therefore, the number of parts constituting the switching transmission wheel is large, the man-hours for manufacturing the parts are large, and the man-hours for assembling are large.

[0010]

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide an automatic winding timepiece having an automatic winding mechanism including a switching transmission wheel which can increase the transmission efficiency of rotation without the risk of bulging or idling. Especially. Another object of the present invention is to provide an automatic winding timepiece having an automatic winding mechanism including a switching transmission wheel having a small number of constituent parts, a small number of parts manufacturing steps, and a small assembly steps. Still another object of the present invention is to provide a switching transmission used in an automatic winding timepiece having an automatic winding mechanism including a switching transmission wheel that can increase the transmission efficiency of rotation without the risk of bulging or idling. To provide a car.

[0011]

According to the present invention, there is provided a rotary weight that can rotate in two directions, a switching transmission wheel for switching rotation of the rotary weight in two directions to rotation in one direction, and a rotation of the switching transmission wheel. In a self-winding timepiece equipped with an automatic winding mechanism configured to be able to wind a mainspring through a transmission train wheel, a switching transmission wheel is provided so as to be rotatable between the switching transmission pinion and the switching transmission pinion. A switching upper car, a switching upper seat fixed to the switching transmission pinion, a switching pawl fixed to the switching transmission pinion, a switching lower car rotatably provided with respect to the switching transmission pinion, and a switching transmission pinion fixed to the switching transmission pinion. The switching transmission base is configured to include the pinion portion.

The switching upper wheel includes a switching upper gear body for receiving the rotation of the rotary weight in one direction, and a switching upper ratchet wheel having a ratchet gear and fixed to the switching upper gear body. The upper gear body and the switching upper ratchet wheel are configured to be rotatable with respect to the switching upper seat between the collar portion of the switching upper seat and the switching pawl. Further, the above-mentioned switching lower wheel has a switching lower gear body for receiving rotation of a rotary weight in a direction other than the one direction, and a switching lower pawl wheel having a ratchet gear and fixed to the switching lower gear body. The switching lower gear body and the switching lower pawl wheel are configured to be rotatable with respect to the switching lower seat between the collar portion of the switching lower seat and the switching pawl. Further, the switching pawl includes an upper actuating portion, an upper spring portion, a base portion, a lower actuating portion, a lower spring portion, and a central hole provided in the base portion, and the upper spring portion is the upper actuating portion. The lower spring portion is provided between the lower actuating portion and the base portion, and the upper actuating portion of the switching pawl is configured to be able to mesh with the ratchet gear of the switching upper pawl wheel. The lower actuating portion of the switching pawl is configured to be able to mesh with the ratchet gear of the switching lower pawl wheel. With the above-described configuration of the self-winding timepiece of the invention, it is possible to eliminate the risk of tension or idling in the self-winding mechanism and to increase the rotation transmission efficiency.

In the self-winding timepiece of the present invention, the upper spring portion of the switching pawl is configured to be perpendicular to the base portion at an upper right angle, and the lower spring portion of the switching pawl is perpendicular to the lower portion at the base portion. Is preferably configured as follows. In the self-winding timepiece of the invention, the switching pawl is configured such that the planar shape when projected on a plane parallel to the base portion is point-symmetrical with respect to the center of the central hole of the switching pawl. Is preferred. In such a structure of the self-winding timepiece of the invention, the number of constituent parts is small, the man-hour for manufacturing the parts is small, and the man-hour for assembling is small.

In the self-winding timepiece of the present invention, the self-winding mechanism includes a rotary weight, a first intermediary wheel that rotates based on the rotation of the rotary weight, and a second intermediary vehicle that rotates based on the rotation of the first intermediary vehicle. The switching upper tier vehicle is configured to rotate based on the rotation of the first intermediary vehicle, and the lower switching tier vehicle is configured to rotate based on the rotation of the second intermediary vehicle. And one or more transmission wheels that are configured to rotate based on the rotation of the transmission wheel, and the mainspring can be wound up based on the rotation of the transmission wheels.

Further, according to the present invention, the rotary weight that can rotate in two directions and the rotation of the rotary weight in two directions are switched to rotation in one direction, and by this rotation in one direction, the mainspring is passed through the transmission train wheel. A switching transmission wheel used for an automatic winding timepiece having an automatic winding mechanism configured to be able to be wound up.

[0016]

According to the automatic winding mechanism of the automatic timepiece of the invention,
There is no risk of squeezing or swinging on the switch transmission vehicle. Further, the switching transmission wheel of the self-winding timepiece according to the present invention can increase the rotation transmission efficiency. Further, the switching transmission wheel of the self-winding timepiece according to the present invention has a small number of constituent parts, a small number of parts manufacturing steps, and a small assembly steps.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of an automatic winding timepiece according to the present invention will be described below with reference to the drawings. (1) Structure on the front side of the movement First, in the embodiment of the self-winding timepiece of the invention, the front side of the movement (the side opposite to the dial of the main plate).
The schematic structure of will be described. With reference to FIGS. 1 to 3 and 7 to 9, in the self-winding timepiece of the present invention, a movement (timepiece mechanical body including a mechanism for driving the timepiece) 100 is
It has a base plate 102 that constitutes the substrate of the movement 100. The winding stem 310 is rotatably incorporated in the winding stem guide hole of the main plate 102. A dial 104 (shown by phantom lines in FIGS. 1, 2, 8, and 9) is attached to the movement 100.

In general, of both sides of the main plate, the side with the dial is called the "back side" of the movement, and the side opposite to the side with the dial is called the "front side" of the movement.
The train wheel incorporated in the "front side" of the movement is referred to as "front train wheel", and the train wheel incorporated in the "back side" of the movement is referred to as "back train wheel". Referring to FIG. 7, the balance 3
40, escape wheel 330, escapement / governing device including pallet 342, fourth wheel 328, third wheel 326, second wheel 32
5. A front train wheel including the barrel wheel 320 and a switching device including a belly button, a boot, a spring, a presser and the like (all not shown) are arranged on the “front side” of the movement 100. Further, a barrel holder 360 that rotatably supports the barrel of the barrel wheel 320, the barrel of the center wheel & pinion 325, the barrel of the third wheel & pinion 326, and the barrel of the fourth wheel & pinion 328. A train wheel bridge 362 that rotatably supports the upper shaft portion of the balance wheel 330, an ankle bridge 366 that rotatably supports the upper shaft portion of the pallet fork 342, and an upper shaft portion of the balance with hairspring 340 can be rotated. The balance with hairspring bridge 366, which is thus supported, is arranged on the “front side” of the movement 100.

(2) Structure of self-winding mechanism Next, the structure of the self-winding mechanism in the embodiment of the self-winding timepiece of the invention will be described. Referring to FIGS. 1 to 3, the automatic winding mechanism includes a rotary weight 210, a first intermediary wheel 212 that rotates based on rotation of the rotary weight 210, and a second intermediary wheel that rotates based on rotation of the first intermediary wheel 212. The vehicle 216, the switching transmission wheel 220 that rotates in one direction based on the rotations of the first intermediate vehicle 212 and the second intermediate vehicle 216, and the first transmission wheel 250 that rotates based on the rotation of the switching transmission wheel 220. Second transmission wheel 252 that rotates based on rotation of transmission wheel 250
And a third transmission wheel 254 that rotates based on the rotation of the second transmission wheel 252. The rotary weight 210 has a train wheel bridge 362.
Inner ring 210a fixed to the plurality of balls 210b
An outer ring 210c, a rotary weight pinion 210d integrally provided with the outer ring 210c, a rotary weight body 210e fixed to the outer ring 210c, and a rotary weight 210f fixed to the rotary weight body 210e. The outer ring 210c is configured to be rotatable with respect to the inner ring 210a via balls 210b.

The first intermediary wheel 212 is the first intermediary gear 212a.
And the first intermediary kana 212b. The most intermediate vehicle 212
Is rotatably provided with respect to the first intermediary wheel pin 102g provided on the main plate 102. The rotary pinion 210d is configured to mesh with the intermediary gear 212a most. The second transfer wheel 216 includes a second transfer gear 216a. The second intermediate gear 216a is configured to mesh with the first intermediate pinion 212b. Upper shaft of the second transfer vehicle 216, switching transmission wheel 22
The upper shaft portion 220a of 0 is rotatably provided with respect to the train wheel bridge 362. The lower shaft portion of the second transfer wheel 216 and the lower shaft portion 220e of the switching transmission wheel 220 are rotatably provided with respect to the main plate 102.

The most transmitted wheel 250 is the most transmitted gear 250a.
And the most handy kana 250b. Second transmission car 252
Includes a second transmission gear 252a. The most transmitted 250b
Is configured to mesh with the second transmission gear 252a.
The third transmission wheel 254 includes a third transmission gear 254a and a third transmission pinion 254b. The second transmission gear 252a is configured to mesh with the first transmission pinion 250b and the third transmission gear 254a. The upper shaft portion of the first transmission wheel 250 and the upper shaft portion of the second transmission wheel 252 are rotatably provided with respect to the transmission bridge 270. The lower shaft portion of the first transmission wheel 250 and the lower shaft portion of the second transmission wheel 252 are rotatably provided with respect to the barrel holder 360. The third transmission wheel 254 is rotatably provided with respect to the third transmission wheel pin 360g provided on the barrel holder 360. The third transmission pinion 254b is configured to engage with the square hole wheel 316.

(3) Structure of Switching Transmission Wheel Next, the structure of the switching transmission wheel in the embodiment of the self-winding timepiece of the invention will be described. With reference to FIGS. 1 to 4, a switching transmission wheel 220 includes a switching transmission pinion 222 and an upper switching wheel 23 provided rotatably with respect to the switching transmission pinion 222.
0 and the switching upper seat 236 fixed to the switching transmission pinion 222
And the switching pawl 238 fixed to the switching transmission pinion 222
And a switching lower wheel 240 rotatably provided to the switching transmission pinion 222 and a switching lower seat 246 fixed to the switching transmission pinion 222. The switching transmission pinion 222 includes an upper shaft portion 222a, a pinion portion 222b, and a first step portion 22.
2c, a second step portion 222d, and a lower shaft portion 222e. The switching upper seat 236 is fixed to the first step portion 222c.
The switching lower seat 246 is fixed to the second step portion 222d.

The switching upper car 230 is the first intermediary kana 212.
The switching upper gear body 232 that meshes with b and the ratchet gear 2
And a switching upper ratchet wheel 234 fixed to the switching upper gear body 232. The switching upper gear body 232 and the switching upper ratchet wheel 234 are configured to be rotatable with respect to the switching upper seat 236 between the collar portion of the switching upper seat 236 and the switching pawl 238. The lower switching vehicle 240 is the second intermediary vehicle 2
The switching lower gear body 2 that meshes with the 16 second gear 216a
42 and a switching lower ratchet wheel 244 having a ratchet gear 244h and fixed to the switching lower gear body 242. The switching lower gear body 242 and the switching lower pawl wheel 244 are configured to be rotatable with respect to the switching lower seat 246 between the collar portion of the switching lower seat 246 and the switching pawl 233.

Referring to FIGS. 4-6, the switching pawl 238.
Is an upper operating portion 238b, an upper spring portion 238c, a base portion 238d, a lower operating portion 238f, and a lower spring portion 238g.
And a central hole 238k provided in the base portion 238d. The upper spring portion 238c of the switching pawl 238 is the upper operating portion 2
38b and the base portion 238d. The lower spring portion 238g of the switching pawl 238 is provided between the lower operation portion 238f and the base portion 238d.

The switching pawl 238 is made of an elastic material such as stainless steel. The center hole of the base portion 238d is fixed to the switching upper seat 238. Therefore, the switching pawl 238 is configured to rotate integrally with the switching transmission pinion 222. The upper actuating portion 238b of the switching pawl 238 is configured to be able to mesh with the ratchet gear 234h of the switching pawl wheel 234. Lower working portion 23 of switching pawl 238
8f is a ratchet gear 244h of the switching lower ratchet wheel 244.
It is configured to be able to mesh with. Switching claw 2
The upper spring portion 238c of 38 is preferably configured so as to be perpendicular to the base portion 238d at a right angle. The upper actuating portion 238b of the switching pawl 238 is formed at the tip of the upper spring portion 238c. With this configuration, the upper actuating portion 238b of the switching pawl 238 is reliably pressed against the ratchet gear 234h of the switching upper pawl wheel 234 by the elastic force of the upper spring portion 238c.

The lower spring portion 238g of the switching pawl 238 is preferably constructed so as to be at a right angle downward with respect to the base portion 238d. The lower operating portion 238f of the switching pawl 238 is formed at the tip of the lower spring portion 238g. With this configuration, the lower actuating portion 238f of the switching pawl 238 is connected to the lower spring portion 2
The elastic force of 38 g reliably presses the ratchet gear 244 h of the switching lower ratchet wheel 244. Base part 23
Switching claw 23 when projected on a plane parallel to 8d
The plane shape of No. 8 is preferably point-symmetrical with respect to the center of the center hole 238k of the switching pawl 238. With this configuration, the switching pawl 238 is surely pressed against the ratchet gear 234h of the switching upper pawl wheel 234 and the ratchet gear 244h of the switching lower pawl wheel 244 in a well-balanced manner. .

(4) Operation of the automatic winding mechanism Next, the operation of the automatic winding mechanism in the embodiment of the automatic winding timepiece of the invention will be described. With reference to FIGS. 3 and 5, the operation when the rotary weight 210 rotates in the clockwise direction will be described. When the rotary weight 210 rotates clockwise, the first intermediary wheel 212 rotates counterclockwise. When the first intermediary vehicle 212 rotates counterclockwise,
The switching upper gear body 232 rotates clockwise. When the switching upper gear body 232 rotates clockwise, the switching upper ratchet wheel 234 also rotates clockwise. In this state, the upper actuating portion 238b of the switching pawl 238 has the switching upper pawl wheel 234.
Meshes with the ratchet gear 234h. Therefore, since the switching upper pawl wheel 234 rotates clockwise, the switching pawl 238 also rotates clockwise, so that the switching transmission pinion 222 also rotates clockwise.

When the first intermediary wheel 212 rotates counterclockwise, the second intermediary wheel 216 rotates clockwise. When the second transfer vehicle 216 rotates clockwise,
The switching lower gear body 242 rotates counterclockwise. When the switching lower gear body 242 rotates counterclockwise, the switching lower ratchet wheel 244 also rotates counterclockwise. In this state, the lower actuating portion 238f of the switching pawl 238 operates so as to escape from the ratchet gear 244h of the switching pawl 244. Therefore, the switching transmission pinion 222 cannot be rotated by the rotation of the switching lower gear body 242.

Next, with reference to FIGS. 3 and 6, the operation when the rotary weight 210 rotates counterclockwise will be described. When the rotary weight 210 rotates counterclockwise, the first intermediary wheel 212 rotates clockwise. When the first intermediary wheel 212 rotates clockwise, the switching upper gear body 232 rotates counterclockwise. Switching upper gear body 2
When 32 rotates counterclockwise, the switching upper ratchet wheel 23
4 also rotates counterclockwise. In this state, the upper operating portion 238b of the switching pawl 238 operates so as to escape from the ratchet gear 234h of the switching pawl wheel 234. Therefore, the switching transmission pinion 222 cannot be rotated by the rotation of the switching upper gear body 232.

When the first intermediary vehicle 212 rotates clockwise, the second intermediary vehicle 216 rotates counterclockwise. When the second intermediate wheel 216 rotates counterclockwise, the switching lower gear body 242 rotates clockwise. When the switching lower gear body 242 rotates clockwise, the switching lower ratchet wheel 244 also rotates clockwise. In this state, the lower operating portion 238f of the switching pawl 238 meshes with the ratchet gear 244h of the switching pawl 244. Therefore, since the switching lower pawl 244 rotates clockwise, the switching pawl 238 also rotates clockwise.
The switching transmission pinion 222 also rotates clockwise.

As described above, in the automatic winding mechanism of the automatic winding timepiece of the invention, the switching transmission is carried out both when the rotary weight 210 rotates clockwise and when the rotary weight 210 rotates counterclockwise. The pinion 222 can rotate in a fixed direction, that is, a clockwise direction. Such operation is surely performed by the switching transmission wheel 220 of the self-winding timepiece of the invention provided with the switching pawl 238. In the automatic winding mechanism of the automatic winding timepiece of the invention, the rotation direction of the switching transmission pinion 222 is constant regardless of the direction in which the rotary weight 210 rotates, and therefore, based on the rotation of the switching transmission pinion 222,
The ratchet wheel 316 can be rotated only in one direction through the rotation of the first transmission wheel 250 and the third transmission wheel 252. Referring to FIGS. 3 and 8, by rotating the ratchet wheel 316, the mainspring 322 in the barrel complete 320 can be wound up in only one direction.

(5) Structures and Functions of Escape / Governor and Front Train Wheel Next, structures of the escape / gear controller and front train wheel in the embodiment of the self-winding timepiece of the invention will be described. . Shidori,
The position of the winding stem 310 in the axial direction is determined by a switching device including a boot, a spring, and a presser.
The winding stem 310 moves the movement 10 along the rotation axis direction.
When the winding stem 310 is rotated in the first winding stem position (0th step) closest to the inner side of 0, the pinion wheel (not shown) is rotated through the rotation of a clutch wheel (not shown). No.) rotates. A round hole wheel (not shown) is configured to rotate by rotation of a pinion wheel. The ratchet wheel 316 rotates by the rotation of the ratchet wheel. The barrel complete 320 is provided with a barrel gear 320d, a barrel stem 320f, and a mainspring 322. By rotating the ratchet wheel 316, the mainspring 322 housed in the barrel wheel 320 is wound up.

The center wheel & pinion 325 is configured to rotate by the rotation of the barrel wheel 320. The center wheel & pinion 325 includes a second gear wheel 325a and a second pinion 325b. Barrel barrel 32
0d is configured to mesh with the second pinion 325b.
The third wheel & pinion 326 is configured to rotate by the rotation of the second wheel & pinion 325. The third wheel & pinion 326 includes a third wheel 326a and a third pinion 326b. Fourth wheel 328, third wheel 32
It is configured to rotate once per minute by rotating 6 times.
The fourth wheel & pinion 328 has a fourth wheel 328a and a fourth pinion 328b.
Including and The third gear 326a is configured to mesh with the fourth pinion 328b. The escape wheel & pinion 330 is configured to rotate under the control of the pallet fork 342 by the rotation of the fourth wheel & pinion 328. The escape wheel 330 is the escape wheel 3
Includes 30a and 330g. Fourth gear 32
8a is configured to mesh with the escape pinion 330b. The barrel complete 320, the second wheel & pinion 325, the third wheel & pinion 326, and the fourth wheel & pinion 328 form a front train wheel.

The escapement / speed control device for controlling the rotation of the front train wheel includes a balance with hairspring 340, an escape wheel & pinion 330, and an pallet fork 342. That is, the escape wheel 330 constitutes the pallet fork 342, and the balance with hairspring 340 constitutes the escapement / speed control device.
The balance with hairspring 340 includes a balance stem 340a and a balance wheel 340b.
And a hairspring 340c. Hairspring 34
Reference numeral 0c is a thin leaf spring in the form of a spiral (spiral) having a plurality of turns. The balance with hairspring 340 is rotatably supported with respect to the main plate 102 and the balance bridge 366.

The minute wheel 324 includes a minute wheel 324a and a cannon pinion 3
24b and. The minute gear 324a is configured to mesh with the third pinion 326b. Minute wheel 324a and cylinder pinion 3
24b is configured to rotate as a unit. The cannon pinion 324b and the minute gear 324a are provided with a slip mechanism configured so that the cannon pinion 324b can slip with respect to the minute gear 324a. The rotation of the third wheel & pinion 326 causes the minute wheel 324 to rotate, whereby the date driving wheel 348 is rotated. Hino's back wheel 348 is the sun's back gear 348
a and a back pinion 348b. The cannon pinion 324b is configured to mesh with the date back gear 348a. The hour wheel 354 is configured to mesh with the back pinion 348b. The hour wheel 354 is configured to rotate once every 12 hours by the rotation of the day wheel & pinion 348. The minute driving wheel 324, the day driving wheel 348, and the hour wheel 354 form a back train wheel.

The barrel wheel 320 and the center wheel & pinion 325 are the main plate 10
2 and the barrel holder 360 are rotatably supported. That is, the upper shaft portion of the barrel wheel 320, the upper shaft portion of the center wheel & pinion 325, and the upper shaft portion of the escape wheel & pinion 330 are rotatably supported with respect to the train wheel bridge 362. Also, the barrel car 320
The lower shaft portion of the second wheel & pinion 325 is rotatably supported by the main plate 102. Third wheel 326, fourth wheel 32
8. The escape wheel & pinion 330 is rotatably supported with respect to the main plate 102 and the train wheel bridge 362. That is, the upper shaft portion of the third wheel & pinion 326, the upper shaft portion of the fourth wheel & pinion 328, the escape wheel 33.
The upper shaft portion of 0 is rotatably supported with respect to the train wheel bridge 362.

Further, the lower shaft portion of the third wheel & pinion 326, the escape wheel & pinion 3
The lower shaft portion of 30 is rotatably supported with respect to the main plate 102. The lower shaft portion of the fourth wheel & pinion 328 is rotatably supported in the center hole of the center pipe 102j fixed to the main plate 102. The pallet fork 342 is rotatably supported with respect to the main plate 102 and the pallet fork 364. That is, the upper shaft portion of the pallet fork 342 is rotatably supported with respect to the pallet bridge 364. The lower shaft portion of the pallet fork 342 is rotatably supported with respect to the main plate 102.

When the barrel wheel 320 is rotated, the second wheel 32 is rotated.
The minute wheel & pinion 324 rotates once per hour through the rotation of the third wheel & pinion 326. The minute hand 352 attached to the cannon pinion 324b of the minute indicator 324 displays "minute". By the rotation of the center wheel & pinion 325, the rotation of the third wheel & pinion 326 causes the fourth wheel & pinion 328 to rotate.
Rotates once per minute. The second hand 358 attached to the fourth wheel & pinion 328 displays "second". Based on the rotation of the minute driving wheel 324, the hour wheel 354 is rotated through the rotation of the day driving wheel 348.
Rotate once every two hours. Hour hand 3 attached to the hour wheel 354
56 displays "hour".

When the winding stem 310 is pulled out and is in the second winding stem position (first stage), the winding stem 310 is rotated.
The date driving wheel 348 can be rotated through the rotation of a clutch wheel (not shown) and a small iron wheel (not shown). In this state, when the day driving wheel 348 is rotated, the tubular pinion 324
Since b and the hour wheel 354 can be rotated, the time on the clock can be corrected. In this state, the cannon pinion 324b can slip with respect to the minute gear 324a by a slip mechanism provided on the cannon pinion 324b and the minute gear 324a.

[Brief description of drawings]

FIG. 1 is a schematic partial cross-sectional view showing an automatic winding mechanism including a rotary weight, a first transfer wheel, and a switching transmission wheel in an embodiment of an automatic winding timepiece of the invention.

FIG. 2 is a schematic partial cross-sectional view showing an automatic winding mechanism including a rotary weight, a first intermediary wheel, a second intermediary wheel and a switching transmission wheel in the embodiment of the automatic timepiece of the invention.

FIG. 3 is a plan view showing a schematic configuration of an automatic winding mechanism in the embodiment of the automatic winding timepiece of the invention.

FIG. 4 is a cross-sectional view showing a structure of a switching transmission wheel in the embodiment of the self-winding timepiece of the invention.

FIG. 5 is a plan view showing the operating principle of the switching transmission wheel when the first intermediary vehicle rotates counterclockwise in the embodiment of the self-winding timepiece of the invention.

FIG. 6 is a plan view showing the operating principle of the switching transmission wheel when the first intermediary vehicle rotates clockwise in the embodiment of the self-winding timepiece of the invention.

FIG. 7 is a plan view showing a schematic shape of the front side of the movement in the embodiment of the self-winding timepiece of the present invention (in FIG. 7, some parts such as the self-winding mechanism are omitted and Parts are shown in phantom).

FIG. 8 is a schematic partial sectional view showing a portion from the barrel to the hour wheel in the embodiment of the self-winding timepiece of the invention.

FIG. 9 is a schematic partial sectional view showing a portion from the escape wheel & pinion to the balance with hairspring in the embodiment of the self-winding timepiece of the invention.

FIG. 10 is a schematic partial cross-sectional view showing an automatic winding mechanism including a rotary weight, a first transfer wheel and a switching transmission wheel in a conventional automatic winding timepiece.

FIG. 11 is a plan view showing the operating principle of the switching transmission wheel when the first intermediary wheel rotates counterclockwise in the conventional automatic winding timepiece.

FIG. 12 is a plan view showing the operating principle of the switching transmission wheel when the first intermediary wheel rotates clockwise in the conventional self-winding timepiece.

[Explanation of symbols]

100 movements 102 Main plate 104 dial 210 oscillating weight 212 most agency vehicle 216 Second Broker 220 switching transmission vehicle 222 Switch transmission 230 switching upper car 236 switch seat 238 switching claw 240 switching lower car 246 switching base 232 Switching upper gear body 234 Switching upper wheel 242 Switching lower gear body 244 Switching lower pawl car 250 most transmitted car 252 second transmission car 254 third transmission car 320 barrel car 324 minutes 325 second wheel 326 Third wheel 328 Fourth wheel 330 escape wheel 340 Temp 342 Uncle

Claims (4)

[Claims] 1. A rotary weight rotatable in two directions, a switching transmission wheel for switching the rotation of the rotary weight in two directions to rotation in one direction, and a mainspring via a transmission train wheel by rotation of the switching transmission wheel. In an automatic winding timepiece having an automatic winding mechanism configured to be able to be wound up, a switching transmission wheel (220) has a switching transmission pinion (222),
A switching upper wheel (230) rotatably provided with respect to the switching transmission pinion (222), a switching upper seat (236) fixed to the switching transmission pinion (222), and a switching transmission pinion (22).
2), the switching claw (238) fixed to the switching transmission pinion (222) rotatably provided with respect to the switching transmission pinion (222), and the switching bottom seat (240) fixed to the switching transmission pinion (222). 246), and the switch transmission pinion (222) is a pinion part (222b).
The switching upper car (230) includes a rotary weight (21) in one direction.
Switching upper gear body (232) for receiving the rotation of (0)
And a switching upper ratchet wheel (234) having a ratchet gear (234h) and fixed to the switching upper gear body (232), the switching upper gear body (232) and the switching upper ratchet wheel (2).
34) is a collar of the switching upper seat (236) and a switching pawl (2).
38) is configured to be rotatable with respect to the switching upper seat (236), and the lower switching wheel (240) receives rotation of the rotary weight (210) in another direction different from the one direction. A switching lower gear body (242) and a switching lower ratchet wheel (244) having a ratchet gear (244h) and fixed to the switching lower gear body (242). Switching lower pawl (244)
Is the collar of the switching lower seat (246) and the switching pawl (238).
Is configured to be rotatable with respect to the switching lower seat (246), and the switching pawl (238) includes an upper actuating portion (238b), an upper spring portion (238c), and a base portion (238d). And a lower actuating portion (238f), a lower spring portion (238g), and a central hole (238k) provided in the base portion (238d), and the upper spring portion (238c) being the upper actuating portion (238b). It is provided between the base part (238d) and the lower spring part (23
8g) is a lower operation part (238f) and a base part (238d)
And the upper actuating portion (238b) of the switching pawl (238) is configured so as to be able to mesh with the ratchet gear (234h) of the switching pawl wheel (234). An automatic winding timepiece characterized in that the lower actuating portion (238f) is configured so as to be able to mesh with the ratchet gear (244h) of the switching lower ratchet wheel (244). 2. The upper spring portion (238) of the switching pawl (238).
c) is configured so as to be at a right angle upward with respect to the base portion (238d), and the lower spring portion (2) of the switching pawl (238) is formed.
38g) is configured such that it is perpendicular to the base portion (238d) at a right angle, and the self-winding timepiece according to claim 1. 3. The switching pawl (238) has a base portion (23).
8d) when projected onto a plane parallel to 8d) so that the planar shape is point-symmetrical with respect to the center of the central hole (238k) of the switching pawl (238). The self-winding timepiece according to claim 1 or claim 2. 4. A rotary weight that is rotatable in two directions, and rotation of the rotary weight in two directions is switched to rotation in one direction, and by this rotation in one direction, the mainspring can be wound up via a transmission train wheel. In a switching transmission wheel used for an automatic timepiece having an automatic winding mechanism configured as described above, the switching transmission wheel (220) includes a switching transmission pinion (222),
A switching upper wheel (230) rotatably provided with respect to the switching transmission pinion (222), a switching upper seat (236) fixed to the switching transmission pinion (222), and a switching transmission pinion (22).
2), the switching claw (238) fixed to the switching transmission pinion (222) rotatably provided with respect to the switching transmission pinion (222), and the switching bottom seat (240) fixed to the switching transmission pinion (222). 246), and the switch transmission pinion (222) is a pinion part (222b).
The switching upper car (230) includes a rotary weight (21) in one direction.
Switching upper gear body (232) for receiving the rotation of (0)
And a switching upper pawl wheel (234) having a ratchet gear (234h) and fixed to the switching upper gear body (232), the switching upper gear body (232) and the switching upper pawl wheel (234).
Is the collar of the switching seat (236) and the switching pawl (238).
Is configured to be rotatable with respect to the switching upper seat (236), and the lower switching wheel (240) receives rotation of the rotary weight (210) in another direction different from the one direction. The switching lower gear body (242) and the switching lower ratchet wheel (244) having the ratchet gear (244h) and fixed to the switching lower gear body (242) are included. Claw wheel (244)
Is the collar of the switching lower seat (246) and the switching pawl (236).
Is configured to be rotatable with respect to the switching lower seat (246), and the switching pawl (238) includes an upper actuating portion (238b), an upper spring portion (238c), and a base portion (238d). And a lower actuating portion (238f), a lower spring portion (238g), and a central hole (238k) provided in the base portion (238d), and the upper spring portion (238c) being the upper actuating portion (238b). It is provided between the base part (238d) and the lower spring part (23
8g) is a lower operation part (238f) and a base part (238d)
And the upper actuating portion (238b) of the switching pawl (238) is configured so as to be able to mesh with the ratchet gear (234h) of the switching pawl wheel (234). The lower transmission part (238f) is configured so as to be capable of meshing with the ratchet gear (244h) of the lower switching ratchet wheel (244).