JP4244643B2 - Clock with chronograph - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a chronograph timepiece.
[0002]
[Background]
Conventionally, analog display chronograph watches equipped with hands have chronograph hands such as second chronograph hands and minute chronograph hands, and start time measurement by operating the start button provided on the watch. The chronograph wheel equipped with the chronograph hands is transmitted with the driving force from the driving source and starts driving. When the stop button is operated, the time measurement is stopped, the chronograph hand is stopped, and the measurement time is displayed by the chronograph hand. Here, the start button and the stop button are commonly used so that the start and stop can be alternately repeated. When the reset button provided separately from the start and stop buttons is operated from the state in which the chronograph hands are stopped, each chronograph hand returns to the zero position (hereinafter referred to as nulling). At the same time as the return to zero, the electronic circuit that controls the driving of the chronograph is reset, and the next start is possible.
[0003]
Some electronic timepieces with chronographs have independent motors corresponding to each of the second chronograph wheel and the minute chronograph wheel, and the motors are controlled by an electronic circuit to start, stop and return to zero. However, in this configuration, a motor corresponding to a plurality of chronograph vehicles is required, and the number of parts is large and the structure is complicated. Further, since the return to zero by the motor is driven at a predetermined step speed to return to zero, the time required for return to zero may become longer depending on the stop position of the chronograph hand.
On the other hand, the mechanical nulling structure used in the conventional mechanical timepiece has the advantage that it can instantaneously null regardless of the stop position of the chronograph hands. Therefore, a chronograph timepiece has been proposed that combines a mechanical nulling structure used in a mechanical timepiece with electronic control.
[0004]
The mechanism for mechanically returning the chronograph hands has a structure in which a heart cam provided in a chronograph wheel for holding the chronograph hands and displaying an elapsed time is pressed and returned to zero. Here, in order to make the three states of start, stop, and zero return stable and control with moderation in operation, there may be a structure provided with an operating cam. The operation cam includes a gear portion and a column portion, and the rotation position of the operation cam is controlled by an operation cam jumper. By pressing the start / stop button, the operating cam is fed one pitch at a time, and the start of the operating lever is restricted to two positions: the position where the tip of the operating lever hits the wall of the column of the operating cam and the position between the adjacent columns. , Making two states of stop. Further, when returning to zero, the resetting button is pressed and the hammer transmission lever is interlocked to perform zeroing. However, in the start state, the tip of the second hammer transmission lever is in contact with the column portion of the operating cam, and zeroing is not possible. In the stop state, the tip of the second hammer transmission lever is inserted between the columns of the operating cam so that the return can be zeroed. In such a structure, three states of start, stop, and zero return are created at the restriction position of the operating cam that rotates in conjunction with the operation button (see, for example, Patent Document 1).
[0005]
A structure for simplifying the nulling mechanism has also been proposed (see Patent Document 2). In Patent Document 2, when the reset button is pressed, the hammer, the start / stop lever, and the hammer transmission lever, which are always engaged through the return spring portion of the battery pushing plate, are interlocked, and the hammer transmission lever is The heart cam provided in the chronograph wheel with the pressing part is pressed and hammered back. Here, the hammer transmission lever always keeps pressing the heart cam with a spring portion formed on the battery pressing plate.
When the start / stop button is pressed, the heart cam is pressed by the hammer transmission lever pressing part in conjunction with the start / stop lever and hammer return lever via the return spring part of the battery pressing plate provided on the outer periphery of the movement. Is released. The position of the hammer transmission lever is regulated by engaging with a notch portion of a spring portion provided in the battery pushing plate.
Therefore, the position of the start / stop lever is also regulated by the hammer transmission lever so as to be separated from the start / stop button. When the start / stop button is pressed again, the start / stop lever and hammer return lever are not linked to the button operation, and the return spring of the battery pressing plate provided on the movement outer periphery is on the start / stop button side. When the button is released, only the button is returned by the return spring, and the switch input is turned OFF. In this way, the start and stop operations are repeated.
[0006]
[Patent Document 1]
W099 / 54792 (pages 3-8)
[Patent Document 2]
Utility Model Registration No. 2605696 ([0010-0022])
[0007]
[Problems to be solved by the invention]
In such Patent Document 1, by restricting the position of the column portion of the operation cam, the positions of the start / stop button, the operation lever interlocked with the operation of the reset button, and the hammer transmission lever are controlled, and the start / stop The three states of return zero are stably provided, and erroneous operation can be prevented. However, the number of parts is large, the structure is complicated, and there are problems in assembling.
According to Patent Document 2, when the start / stop button is pressed, the start / stop button and the hammer lever are interlocked and the switch is input, but when the stop operation is performed, the start / stop button can The stop lever and hammer transmission lever are not linked and only switch input is made.
In such a structure, the number of parts can be reduced and the configuration can be simplified. However, in the case of a stop operation, there is no moderation of the operation and the button is simply pushed because it is only electrically turned on and off. Therefore, the structure is easy to misoperate.
[0008]
The object of the present invention is to solve the problems of the conventional example, realize a mechanical zero return structure of the chronograph needle with a small number of parts, simplify the structure, improve the assemblability, and have a sense of moderation. It is to provide a chronograph timepiece that can be operated reliably.
[0009]
[Means for Solving the Problems]
  A timepiece with chronograph according to the present invention has a chronograph hand for displaying chronograph time, and has a heart cam and a chronograph wheel for transmitting a driving force from a driving source to the chronograph wheel. A chronograph train wheel, a zero return position that presses the heart cam and a hammer that can move to a position away from the heart cam;First 1 An external operation member ofWhen the hammer is pressed against the heart cam,AboveAn actuating lever that is moved to a position away from the heart cam in conjunction with a pushing operation of the first external operating member, and is positioned at a fixed position except during operation of the first external operating member; ,A second external operation member;A hammer transmission lever that regulates the hammer in a position in pressure contact with the heart cam in conjunction with the pressing operation of the second external operation member;An actuating lever positioning member that engages with the actuating lever; and a hammer transmission lever positioning member that engages with the hammer transmission lever, wherein the actuating lever positioning member operates the first external operation member. An elastic portion that can be elastically deformed by a pressing force at the time, and a restricting portion that positions the operating lever at a fixed position by using an elastic force of the elastic portion except when the first external operation member is operated, The hammer transmission lever positioning member includes an elastic portion that can be elastically deformed by any of the pressing force when operating the first external operation member and the pressing force when operating the second external operation member. A restricting portion that uses the elastic force of the elastic portion to position the hammer transmission lever at a position when the hammer is separated from the heart cam and a position when the heart cam is pressed.It is characterized by having.
[0010]
Here, as each positioning member, for example, a plate material is processed, an elastic portion that is extended from the base side and can be elastically deformed, and a concave portion is formed on the distal end side of the elastic portion, and an operating lever or hammer transmission A click spring or the like provided with a restricting portion that can engage with a shaft protruding from the lever can be used.
  According to the present invention, the actuating lever moves the hammer in pressure contact with the heart cam to a position away from the heart cam in conjunction with the pushing operation of the first external operating member. It is positioned at a fixed position by the positioning member except during operation. That is, the operating lever operates in conjunction with the pushing operation of the first external operation member, and when the hammer is in pressure contact with the heart cam during the operation, the hammer is moved. If the needle is away from the heart cam, the hammer is not moved. For this reason, after the hammer is moved to a position away from the heart cam and then the pushing operation of the first external operation member is released, the operation lever is moved to the home position, that is, the position before being pushed by the first external operation member. Positioned back. Therefore, when the first external operation member is pushed again, the operating lever that has been positioned at a fixed position is also pushed, so that a sense of moderation can be obtained during operation and there is no sense of moderation. It is possible to prevent erroneous operations such as switching on even if pressed.
Further, in the present invention, the elastic force acts so as to return the operating lever to the fixed position by the elastic portion of the operating lever positioning member. For this reason, when the pushing operation of the first external operation member is released and the pushing force of the first external operation member does not act on the operation lever, the operation lever is automatically returned to the fixed position by the elastic force of the elastic portion. Then, the restriction portion is positioned at a position before the first external operation member is operated.
When the second external operation member is pressed, the hammer transmission lever positioning member presses and regulates the hammer transmission lever at the restricting portion at a position where the hammer moves against the heart cam. When the operating member is pushed, the position of the hammer transmission lever is regulated by the regulating portion so that the hammer is held at a position away from the heart cam. The positioning member for the hammer transmission lever is urged by its elastic force so as to maintain the hammer transmission lever in the two restricted positions. When the force exceeding the elastic force is applied to the hammer transmission lever, Move from the set position.
The positioning member can stably regulate the position of the operating lever and hammer transmission lever by the elastic force of the elastic part and the restricting part. When operating the external operation member, for example, from the restricting part made concave, for example, of the positioning member Since a predetermined operating force is required when exiting, a sense of moderation can be obtained and erroneous operation can be prevented. Accordingly, by appropriately adjusting the shape of the restricting portion of the positioning member and the elastic force of the elastic portion, it is possible to control the feeling of moderation during operation, and it is possible to obtain an operational feeling with good operability and moderate moderation.
[0011]
In addition, the hammer that is distant from the heart cam is returned to the position where it is in pressure contact with the heart cam in conjunction with the pressing operation of the second external operation member, and is regulated. For this reason, a zero return operation can be realized by pushing the second external operation member.
Furthermore, the hammer is regulated to a position where the pressure contact is released away from the zero return position where the heart cam is pressed in conjunction with the pushing operation of the first external operation member. For example, the chronograph hand is driven by a motor. In doing so, the chronograph hands can be driven by driving the motor, and the chronograph hands can be stopped by stopping the motor.
Therefore, if a switch or the like that is linked to the operation of the first external operation member or the operating lever is provided, and each time the first external operation member is pushed, the start and stop of the motor drive are repeated alternately, Chronograph start / stop operation can be realized.
For this reason, when realizing three operations of start, stop, and zero return, which are general operation specifications of a chronograph, in the present invention, main components are the three components of a hammer, hammer transmission lever, and operating lever. It is possible to provide a simple structure and improve the assemblability.
[0012]
In the chronograph-equipped timepiece of the invention, the hammer transmission lever includes a first hammer transmission lever and a second hammer transmission lever, and each hammer transmission lever includes a rotation shaft at an intermediate portion. Each end portion is rotatably arranged, and one end portions are connected to each other so as to be rotatable and slidable, and the other end portion of the first hammer transmission lever is a second end portion. It is preferable that the other end of the second hammer transmission lever is disposed so as to be able to come into contact with the external operation member, and can be brought into contact with the hammer.
[0013]
In the chronograph timepiece, various layouts of the chronograph wheel and the external operation member for displaying the chronograph time can be considered.
For this reason, for example, the hammer transmission lever may be brought into direct contact with the second external operation member, and the hammer transmission lever may be directly operated by the pressing operation of the second external operation member.
On the other hand, as in the present invention, between the second external operation member and the hammer, the first hammer transmission lever pushed by the second external operation member and the second engaged with the hammer. If the hammer transmission lever is disposed and the hammer is moved to a position where it is pressed against the heart cam via the first and second hammer transmission levers by pushing the second external operation member, Even if the layout of the external operation member changes, the function of the present invention can be easily obtained. Further, the layout can be configured even if the position of the other levers constituting the chronograph wheel holding the chronograph hands is changed.
[0016]
In the timepiece with chronograph of the present invention, the positioning member for the operating lever and the positioning member for the hammer transmission lever may be formed on different members, but may be formed at different positions on the same member. preferable.
[0017]
If each positioning member is formed on the same member, there are effects such as a reduction in the number of parts, simplification of the structure, and improvement in assemblability compared to the case where the positioning members are formed on different members. Moreover, since it is comprised with the same member, the dispersion | variation in a relative position can also be suppressed, the mutual positional accuracy of an operation lever and a hammer transmission lever is good, and stable operation is enabled. In each positioning member, the shape of the restricting portion, the shape of the elastic portion, and the position may be appropriately set according to the configuration of the operating lever and the hammer transmission lever.
[0018]
In the chronograph timepiece of the invention, when the hammer is in pressure contact with the heart cam, the first external operation member interlocked with the operating lever is pushed to release the hammer from the heart cam. The graph hand starts,
When the hammer is separated from the heart cam, pressing the first external operation member stops the chronograph hand, and when the chronograph hand is stopped, the first external operation member is When the chronograph hand is pushed, the chronograph hand starts, and when the hammer is separated from the heart cam, the chronograph hand is preferably returned to zero when the second external operation member is pushed.
[0019]
When the hammer is pressed against the heart cam (returns to zero), when the first external operation member is pressed, the operating lever is pushed and the hammer moves to a position away from the heart cam. The graph hand starts. Subsequently, when the first external operation member is pushed, the operating lever is pushed and the chronograph hands are stopped. When the first external operation member is pressed while the chronograph hand is stopped, the chronograph hand starts.
Accordingly, the start and stop are repeated by continuously pressing the first external operation member, the chronograph can be integrated and measured, the operation is simplified, and the operation is not mistaken. In addition, since the start and stop operation members can be used together, the number of parts can be reduced.
[0020]
In the timepiece with chronograph according to the present invention, the operating lever includes a switch input spring that is input by a pressing operation of the first external operation member, and start and stop operations of the chronograph hands by an input of the switch input spring. Is preferably controlled.
[0021]
In a chronograph timepiece in which a chronograph wheel train is driven by an electronic circuit and a chronograph motor as a driving source, it is necessary to transmit a switch input to the electronic circuit in order to operate the chronograph. Therefore, if a switch input spring formed integrally with the operating lever is provided, the switch input spring operates in the same manner as the operating lever, and is input by a push operation of the first external operation member. Since the input is turned off, the switch input can be transmitted to the electronic circuit.
According to such a configuration, since the switch input spring performs the same operation integrally with the operation lever, it is easy to take the movement of the operation lever, the timing of moving away from the heart cam of the hammer and the timing of switch input.
In addition, the switch input spring can be selected in accordance with the layout of the electronic circuit and other levers because the position of the switch input spring can be selected, so that the switch input spring can be provided on the inner side of the movement, and the movement can be reduced in outer size. There is also an advantage.
[0022]
In the chronograph timepiece of the present invention, the chronograph wheel is composed of a shaft portion having a heart cam and a gear portion which meshes with another chronograph wheel train and slip-engages with the shaft portion. Features.
[0023]
According to such a configuration, since the chronograph wheel has a slip mechanism, at the time of zeroing, only the heart cam and the shaft portion of the chronograph wheel are forcibly rotated, and the other gears of the chronograph wheel train are Since it is not rotated, no measurement error occurs.
That is, if the rotor of the chronograph motor is rotated due to the forced rotation of the heart cam, the electromagnetic phase of the rotor may shift, and the motor does not drive with the first pulse when starting the next chronograph There will be a measurement error.
On the other hand, in the present invention, since the slip mechanism is provided, the rotation is not transmitted to the rotor at the time of zero return, so that no measurement error occurs.
Further, since the heart cam instantaneously rotates at the time of return, a rotation load is applied to other chronograph trains. Therefore, by providing the slip mechanism, a load is not applied to the chronograph wheel train during the forced rotation, so that the rotation does not stop in the middle of the return to zero and a stable return to zero can be achieved. It is also possible to prevent the chronograph train from being destroyed by applying a load at the time of forced rotation to a weakly strong portion.
[0024]
The timepiece with chronograph according to the present invention preferably includes a chronograph setting lever for setting any one gear between the driving source of the chronograph wheel train and the chronograph wheel when the chronograph wheel returns to zero.
[0025]
As described above, if the chronograph wheel is provided with a gear slip-engaged with the shaft portion, when the gear returns to zero, the gear slips and only the shaft portion, that is, the chronograph pointer rotates to return to zero. Is done. However, it is conceivable that the slip torque of the slip mechanism becomes larger than the load of the chronograph train wheel.In that case, the slip mechanism does not slip at the time of return to zero, and the chronograph train wheel is rotated. May occur.
On the other hand, in the present invention, since the chronograph setting lever is provided and the gear of the chronograph wheel train is set, the slip function is surely activated by the pressing force of the chronograph setting lever, and when the return to zero, the drive source is reached. This prevents rotation and prevents measurement errors when the chronograph is started.
[0026]
The chronograph timepiece of the present invention is a chronograph that engages with the hammer transmission lever and presses and regulates one of the gears of the chronograph train wheel in conjunction with the pressing operation of the second external operation member. It is preferable to provide a setting lever.
[0027]
If the chronograph setting lever is engaged with the hammer transmission lever and configured to press and correct one of the gears of the chronograph wheel train in conjunction with the pressing operation of the second external operation member, the chronograph The chronograph train can be adjusted according to the action of returning the car. Specifically, it is preferable for the timing that the regulation is effective immediately before the return to zero, and the hammer transmission lever and the chronograph regulation lever are operated by the hammer transmission lever, so that the timing is easy to take.
[0028]
In the chronograph timepiece of the present invention, the chronograph setting lever is engaged with the operating lever, interlocked with the pushing operation of the first external operation member, and can release the setting of the chronograph wheel train. preferable.
[0029]
When starting the chronograph, it is preferable that the chronograph setting lever is released from the gear of the chronograph wheel train before the start switch is input.
Therefore, as in the present invention, the fact that the actuating lever for inputting the start switch and releasing the regulation and the chronograph regulating lever are directly linked has an effect that it is easy to take the timing.
[0030]
In the chronograph timepiece of the invention, the hammer is provided with a pressure contact portion capable of being pressure-contacted with the heart cam, first and second holes, and a rotation shaft, and the operating lever is configured with the first lever. One end portion that comes into contact with the external operation member, the other end portion having an operating shaft that engages with the first hole of the hammer, and a rotation shaft provided between the ends, the hammer transmission The lever includes one end portion that comes into contact with the second external operation member, a shaft member that engages with the second hole of the hammer, and a rotation shaft provided between the end portions, When the hammer is pressing the heart cam, the first hole of the hammer is rotated when the operating lever is rotated in conjunction with the pressing operation of the first external operation member. The operating shaft is in contact with the inner wall of the hole so that the hammer can be moved, and the hammer is moved to the heart cam When the operating lever is rotated in conjunction with the pushing operation of the first external operation member, the operating shaft does not contact the inner wall of the hole and moves relative to the hammer. The second hole of the hammer is formed in a freely movable shape. When the hammer is in pressure contact with the heart cam, the second hole of the hammer is moved along with the rotation of the hammer. When the shaft member of the hammer transmission lever is pushed by the inner wall of the needle and the hammer is separated from the heart cam, the shaft member of the hammer transmission lever contacts the inner wall of the hole. It is preferable that the hammer is formed in a shape capable of restricting movement of the hammer in the direction of pressing against the heart cam.
[0031]
According to such a configuration, the first and second hole shapes of the hammer are appropriately devised, and the operating shaft of the operating lever and the shaft member of the hammer transmission lever are engaged with these holes, A predetermined operation can be realized. For example, if the first hole is substantially triangular and the hammer is away from the heart cam, the operating shaft can move freely in the triangular hole even if the operating lever rotates. Good.
As described above, since the operation can be performed only by appropriately devising the hole shape and the like, the configuration becomes relatively simple and can be reliably operated.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows an external view of the table of this embodiment.
In this timepiece with a chronograph, the hour hand 1 and the minute hand 2 for displaying the normal time arranged on the same axis are arranged in the direction of 6 o'clock with respect to the center of the case 6 of the timepiece 100, and the basic clock second hand for displaying the normal time. 3 is arranged in the direction of about 10 o'clock. The chronograph second hand 4 indicating the second chronograph time is disposed at a position slightly decentered in the 12 o'clock direction from the center of the case 6 of the timepiece 100. The chronograph minute hand 5 for displaying the minute chronograph time is arranged substantially in the direction of 2 o'clock and moves the sector on the sector-shaped scale. This chronograph has a total of 45 minutes.
A central surface of the watch body 100 is provided with a scale indicating a normal time and a scale indicating a chronograph time on the dial 7. The crown 8 for correcting the normal time is arranged at the 3 o'clock direction of the clock body 100, and the start / stop button 9 for starting and stopping is arranged at the 2 o'clock direction. Is provided with a reset button 10 for returning the chronograph hand.
[0033]
FIG. 2 is a perspective view of a main part of the entire movement of the timepiece. Fig. 2 shows a state in which the wheel train on the upper surface of the movement, the circuit retainer, the zero return retainer, etc. are removed. The basic clock train wheel for displaying the normal time and the chronograph train wheel for displaying the chronograph time are shown. The main part is shown.
First, the general structure of the basic clock train for indicating the normal time will be described.
A circuit receiving seat 700 made of synthetic resin is disposed on the upper surface of the ground plane 400. A basic timepiece motor 101, which is a driving source for a basic timepiece, is composed of a basic timepiece coil 102, a basic timepiece stator 103, and a basic timepiece rotor 104. The timing of one step per second is determined by a drive signal from an electronic circuit. The basic clock rotor 104 is rotated, and the drive is decelerated and transmitted to the small second wheel 106 via the fifth wheel 105 and is held by the basic clock second hand 3 (shown in FIG. 1) held by the small second wheel 106. Seconds are displayed. In addition, the vehicle is decelerated and transmitted to the second wheel 111 via the fifth wheel 105, the fourth third intermediate wheel 107, the fourth second intermediate wheel 108, the fourth first intermediate wheel 109, the third wheel 110 and the second wheel. The basic clock minute hand 2 (shown in FIG. 1) held at 111 displays the minute of the normal time. From the second wheel 111, the drive is transmitted to the hour wheel through the minute wheel and displayed at the normal time (not shown). Since these are the same as general electronic timepieces, they will not be described in detail, but the hours, minutes, and seconds of the normal time are laid out and displayed as shown in FIG.
[0034]
The winding stem 130 fixed to the crown 8 (shown in FIG. 1) is supported between the main plate 400 and the circuit seat 700, and by pulling out the winding stem 130, the setting lever 131 and the crown 132 are interlocked to each other. The car 133 meshes with the small iron wheel 134. The small iron wheel 134 sequentially transmits the rotation of the winding stem 130 to the reverse side third intermediate wheel 135, the reverse side second intermediate wheel 136, the reverse side first intermediate wheel 137, and the reverse side wheel 138. The time is corrected. A setting lever 139 is engaged with the setting lever 131, and the fourth intermediate wheel 109 is set in conjunction with the withdrawal of the winding stem 130. The cars and levers constituting the above-mentioned basic timepiece wheel train are supported between a circuit receiving seat 700 and a wheel train receiver 401 (shown in FIG. 4, but the basic timepiece wheel train is omitted). Yes.
[0035]
Next, the chronograph train wheel will be described with reference to FIG. FIG. 3 is an enlarged perspective view of a main part of the chronograph wheel train of FIG.
A chronograph motor 201 that is a drive source of the chronograph train wheel is composed of a chronograph coil 202, a chronograph stator 203, and a chronograph rotor 204. The chronograph rotor 204 is driven to rotate by the drive signal from the electronic circuit, and is transmitted to the second CG wheel 208 via the second CG third intermediate wheel 205, the second CG second intermediate wheel 206, and the second CG first intermediate wheel 207, The chronograph second is displayed by the chronograph second hand 4 (shown in FIG. 1) held in the second CG wheel 208. The second CG wheel 208 is provided with a heart cam 210 for zeroing.
On the other hand, the minute CG wheel 220, which is a minute chronograph wheel, transmits the step drive from the chronograph motor 201 via the minute CG first intermediate wheel 207, the minute CG second intermediate wheel 222, and the minute CG first intermediate wheel 221. Then, the chronograph minute is displayed by the chronograph minute hand 5 (FIG. 1) held in the minute CG wheel 220. The minute CG wheel 220 is provided with a heart cam 224 for zeroing. The second CG first intermediate wheel 207 is provided with a pinion that meshes with the minute CG wheel 220 and a pinion that meshes with the minute CG second intermediate wheel 222 (not shown).
As shown in FIG. 4, the chronograph train wheel is supported between a circuit receiving seat 700 placed on the upper surface of the main plate 400, a circuit holder 600, and a rotary weight receiver 460 (not shown).
[0036]
FIG. 4 is a cross-sectional view showing the configuration of the second CG wheel 208 and the minute CG wheel 220. -
Since the second CG wheel 208 and the minute CG wheel 220 have the same configuration, the second CG wheel 208 will be described in detail as an example.
The second CG wheel 208 includes a second CG axle 211, a heart cam 210, and a second CG gear 209.
A second CG gear 209 is loosely fitted to a lower portion 211 a of the heart cam 210 formed on the second CG axle 211 and is pressed against the lower surface step portion 211 b of the heart cam 210 by the elastic force of the slip spring 212. The slip spring 212 presses the second CG gear 209 with a certain amount of bending by pressing and fixing the slip spring holding seat 213 to the second CG axle 211. The contact portion between the heart cam 210 and the second CG gear 209 is interlocked during chronograph measurement by the frictional force generated by the pressing of the slip spring 212. On the other hand, at the time of return to zero, the heart cam 210 is forced to rotate by pressing the side surface with the hammer 330, the second CG gear 209 and the heart cam 210 slip, and the second CG axle 211 integrated with the heart cam 210 rotates to rotate the chronograph. Return the graph second hand 4 to the 0 second position. The second CG gear 209 and the other chronograph wheel train do not rotate and maintain normal meshing. The nulling operation will be described in detail after FIG. Here, the second CG wheel 208 is supported by a bearing between the circuit seat 700 and the circuit holder 600.
The minute CG wheel 220 has the same structure as the second CG wheel 208 and will not be described in detail, but includes a minute CG wheel shaft 225, a minute CG gear 223, and a heart cam 224. The minute CG gear 223 has a structure that is pressed against the heart cam lower surface step 225 b by the elastic force of the slip spring 226. The minute CG wheel 220 is supported by a bearing between the circuit receiving seat 700 and the rotary weight receiver 460.
When returning to zero, the heart cam 224 is forcibly rotated by the hammer 330, slips with the minute CG gear 223, and the minute CG axle 225 integrated with the heart cam 224 rotates to return the chronograph minute hand 5 to zero. The minute CG gear 223 and the other chronograph wheel train do not rotate and maintain normal meshing.
In the present invention, the slip springs 212 and 226 are configured separately from the second CG gear 209 and the minute CG gear 223, but even if a slip portion is provided in both CG gears, the function thereof is not changed. The heart cam is formed integrally with the CG axle, but may be fixed separately.
[0037]
The configuration of the chronograph will be described with reference to FIGS. FIG. 5 is a main part plan view showing a chronograph zero return state when the reset button is pressed, and FIG. 6 is a main part perspective view showing main components of the zero return mechanism shown in FIG.
5 and 6, the start / stop button 9 as the first external operation member is in the initial position before the button is pressed. The reset button 10 which is the second external operation member shows a state when the pressing operation is performed. The nulling presser 360 forms a nulling presser spring portion 360 a that is partially bent in the direction of the ground plane, and is in contact with the distal end portion 310 a of the transmission lever 310. The transmission lever 310 is provided with a hole 310b at a position corresponding to the transmission lever shaft 600a planted on the resin-molded circuit retainer 600, and is loosely fitted to the transmission lever shaft 600a. An operating shaft 310 c is formed integrally with the transmission lever 310 at the other tip of the transmission lever 310 and is engaged with a track-shaped hole 320 b of the hammer transmission lever 320.
[0038]
The hammer transmission lever 320 is provided with a hole 320a substantially in the center, and is loosely fitted to a rotation shaft 600b formed integrally with the circuit retainer 600. An operating shaft 321 having step portions having two different diameters is planted at the tip end in the direction opposite to the transmission lever 310. The large-diameter side step portion 321 a of the operating shaft 321 is engaged with the substantially rectangular hole 332 of the hammer 330. The small-diameter side step portion 321b (see FIG. 6) of the operating shaft 321 is engaged with the click spring 361. The click spring 361 is a positioning member that positions the hammer transmission lever 320 and is formed integrally with the zero return press 360.
[0039]
The hammer 330 that is linked to the hammer transmission lever 320 has a hole 330a corresponding to the rotary shaft 600c formed in the circuit holder 600, and is loosely fitted to the rotary shaft 600c. In the clockwise center direction of the hammer 330, a surface 330b that contacts the heart cam 224 of the minute CG wheel 220 and a surface 330c that contacts the heart cam 210 of the second CG wheel 208 are provided. The abutting surface 330c side of the hammer 330 is cut by a slit 330d with respect to the abutting surface 330b side and has a spring portion 330e. A substantially triangular hole 331 is formed on the operating lever 340 side, and is engaged with an operating shaft 340 a formed on the operating lever 340.
[0040]
The operating lever 340 has a hole 340b formed at a position corresponding to the rotating shaft 600d formed in the circuit holder 600, and is loosely fitted to the rotating shaft 600d. In addition, a surface 340c with which the button abuts when the button is pressed is formed in the vicinity of the start / stop button 9, which is the first external operation member, by bending in section. A switch input terminal 340d is integrally formed between the button contact surface 340c and the hole 340b. When the start / stop button 9 is pushed, a start provided on the side surface of the circuit board 501 (see FIG. 10). -It is electrically connected to the stop input pattern 502. Further, the actuating lever 340 is formed with a shaft 340e and an actuating shaft 340a on the same surface, and the shaft 340e is formed on the zero return press 360, and a click part 362 which is a positioning member for positioning the actuating lever 340 The operating shaft 340 a is engaged with the substantially triangular hole 331 of the hammer 330.
[0041]
The chronograph setting lever 350 is provided with a hole 350a at a position corresponding to the rotation shaft 401a formed in the train wheel bridge 401 and is loosely fitted so as to be rotatable.
The chronograph setting lever 350 is in the vicinity of the spring portion 350c that contacts the side surface of the projecting portion 401b formed in a track shape on the train wheel bridge 401 and the second CG second intermediate wheel 206, and the second CG second intermediate wheel. A setting portion 350b bent to a position engaging with the cross section 206 is formed, and a beak-shaped tip portion 350d that engages with the tip portion 340f of the operating lever 340 is formed. Further, it engages with a peninsula-shaped protrusion 320 d of the hammer transmission lever 320.
[0042]
Next, the operation of the chronograph will be described with reference to FIGS.
The nulling operation will be described with reference to FIGS.
When the reset button 10 is pressed, the reset button 10 pushes the tip portion 310a of the transmission lever 310 counterclockwise via the spring portion 360a of the zero return press 360. The transmission lever 310 rotates about the transmission lever shaft 600a, and the operation shaft 310c at the other end also rotates counterclockwise.
[0043]
The hammer transmission lever 320 is rotated clockwise by the operation shaft 310c of the transmission lever 310 around the rotation shaft 600b, and the operation shaft 321 at the other end is also rotated clockwise. Then, the inner wall 332a of the substantially rectangular hole 332 provided in the hammer 330 is pushed by the large-diameter side step portion 321a of the operating shaft 321, and the hammer 330 is counterclockwise about the rotation shaft 600c. It can be rotated. By rotation of the hammer 330, the surface 330b facing the end surface of the heart cam 224 of the minute CG wheel 220 and the surface 330c facing the end surface of the heart cam 210 of the second CG wheel 208 press the heart cams 210 and 224, respectively. Each heart cam 210, 224, that is, the chronograph second hand 4 and the chronograph minute hand 5, which are fixed to the second CG axle 211, the minute CG axle 225, are returned to the set position, generally the zero position, that is, return to zero. .
At this time, the second CG wheel 208 side of the hammer 330 is cut by the slit 330d and presses the heart cam 210 by the elastic force of the spring portion 330e, so that the two heart cams 210 and 224 are pressed. Variations in the dimensions of the parts can be absorbed by the spring portion 330e and reliably returned to zero.
[0044]
When the second CG wheel 208 and the minute CG wheel 220 are returned to zero, the second CG gear 209 and the minute CG gear 223 have a slip structure with respect to the second CG axle 211 and the minute CG axle 225, so that the heart cam is returned. Even if zeroed, the other chronograph trains are not rotated.
Therefore, the chronograph wheel train and the chronograph rotor 204 do not rotate, and the chronograph can be accurately started without mutual phase shift.
[0045]
When the zero return operation is completed, the operating shaft 321 of the hammer transmission lever 320 is positioned on the inclined surface portion 361 a of the click spring 361 formed integrally with the zero return press 360 and is urged by the elastic force of the click spring 361. The hammer 330 abuts against the inner wall 332a of the substantially rectangular hole 332 of the hammer 330. For this reason, the hammer transmission lever 320 can hold a stable position.
When the operation of the reset button 10 is released, the reset button 10 and the spring portion 360a of the zero return press 360 return to the positions before the operation. Since the reset button 10, the hammer transmission lever 320, and the hammer 330 are held in a state when the zero return operation is completed, the other levers that engage the transmission lever 310 even if the reset button 10 is repeatedly pressed. The state does not change.
[0046]
When the reset button 10 is pressed to perform a zeroing operation, the chronograph setting lever 350 is disengaged from the peninsula-shaped protruding portion 320d of the hammer transmission lever 320, and thus is counteracted by the elastic force of the spring portion 350c. Rotating clockwise, the setting part 350b presses the second CG second intermediate wheel to set the chronograph train wheel.
When the heart cams 210 and 224 are rotated and returned to zero, the second CG gear 209 and the minute CG gear 223 are provided with a slip structure and the other chronograph wheel trains are not rotated, but the slip torque is reduced to the chronograph wheel. If it exceeds the load on the train, other chronograph trains may be rotated at the time of return. By providing the chronograph setting lever 350, the slip structure can be made to function completely, so that the chronograph wheel train is rotated during the zero return operation without causing the phase of the magnetic pole of the chronograph rotor 204 to be shifted accurately. Chronograph start is possible.
The chronograph setting lever 350 sets the second CG second intermediate wheel 206, but may set other chronograph wheel trains. Further, even if the operation of the reset button 10 is released, the position of the hammer transmission lever 320 does not change, so the chronograph setting lever 350 also keeps its position.
[0047]
At the time of the zero return operation, the start / stop button 9 is in the position before the push operation, the operating lever 340 is positioned by the shaft 340e and the click spring 362 of the zero return press 360, and the switch input terminal 340d is also input by the start / stop input. It is held at a position away from the pattern 502.
Here, as the timing at the time of the zero return operation, the order of reset switch input, chronograph adjustment, and return zero is the order for preventing malfunction, and in the configuration of this embodiment, the chronograph adjustment lever 350 transmits the hammer. Optimal timing can be obtained because of the structure interlocking with the lever 320.
[0048]
Switch input at the time of pressing the reset button 10 will be described with reference to FIGS. 7 is a cross-sectional view of the reset button portion at the time of the zero return operation, and FIG. 8 is a side view from the reset button direction.
When the reset button 10 is pushed (arrow direction), the movement of the reset button 10 is transmitted through the spring portion 360a of the zero return press 360, and the transmission lever 310 is pushed from the position (A) to the position (B). Therefore, as described above, the hammer transmission lever 320 and hammer 330 are interlocked to press-contact the heart cams 210 and 224 to return the chronograph second hand 4 and chronograph minute hand 5 to zero.
In FIG. 8, a reset terminal 701 is planted in the circuit receiving base 700, and one end face of the reset terminal 701 is connected to a reset input pattern 501 a provided on the circuit board 501.
The surface opposite to the reset input pattern 501a of the circuit board 501 is firmly pressed by a reset terminal pressing spring 360b that is a part of the zero return pressing 360 to improve the connection reliability between the reset terminal 701 and the reset input pattern 501a. Yes.
When the reset button 10 is pressed, the tip of the zero return presser spring 360a moves toward the center of the watch, and the input terminal 360c integrally formed with the return zero press 360 contacts the reset terminal 701 in conjunction with the movement. The reset input is turned ON. When the reset input is turned ON, the electronic circuit is reset, the chronograph is set to the initial state, and the first start is possible. When the operation of the reset button 10 is released, the reset button 10 is returned to its original position by a button return spring (not shown) provided on the case, and the zero return pressing spring portion 360a and the input terminal 360c are restored to their original by their own elastic force. , The connection with the reset terminal 701 is turned off, but the state of the chronograph does not change.
Even if the reset button 10 is pressed again, the electronic circuit is configured such that no reset input is accepted unless a start / stop signal is input.
[0049]
Next, the chronograph measurement start operation will be described with reference to FIGS. FIG. 9 is a plan view of a main part showing a state when the start / stop button is pressed, and FIG. 10 is a cross-sectional view when a start switch is input.
When the start / stop button 9 is pushed, the operating lever 340 is pushed by the surface 340c that is in contact with the start / stop button 9, and rotates counterclockwise about the rotation shaft 600e. When the operating shaft 340a formed on the operating lever rotates counterclockwise, the inner wall 331a of the substantially triangular hole 331 of the hammer 330 is pushed, and the hammer 330 is rotated clockwise about the rotating shaft 600c. Rotate.
The contact surfaces 330b and 330c of the hammer 330 with the heart cams 224 and 210 move to positions away from the rotation trajectory range of the heart cams 224 and 210. At the same time, since the peninsular tip 340f of the actuating lever 340 pushes the beak-like tip 350d of the chronograph setting lever 350, the chronograph setting lever 350 rotates around the rotation shaft 401a and the setting portion 350b. Moves to a position away from the second CG second intermediate wheel 206. For this reason, the chronograph train is in a state in which all the regulations are released.
The switch input terminal 340d formed on the operating lever 340 is bent at the tip and disposed on the side surface of the circuit board 501, and the start provided on the end face of the circuit board 501 in accordance with the pressing operation of the start / stop button 9. -Electrically connected to the stop input pattern 502. As a result, the start input is turned ON and chronograph measurement is started.
Here, the optimal timing for the start is the order of canceling the zero return or regulation, and the input of the start switch in order of eliminating the start error. Canceling the zero return state of the hammer 330 and the chronograph wheel train The optimal timing can be obtained because the regulation is canceled with one operating lever.
[0050]
The hammer 330 linked to the actuation lever 340 pushes the actuation shaft 321 of the hammer transmission lever 320 by the inner wall 332a of the substantially rectangular hole 332 and moves it from the inclined surface 361a at the tip of the click spring 361 to the recess 361b. In this state, the position of the hammer transmission lever 320 is determined and held. The transmission lever 310 is returned to a position where the reset button 10 can be pushed.
[0051]
When the start / stop button 9 is pressed, the shaft 340e of the operating lever 340 that engages with the click spring 362 gets over the slope of the recess 362a at the tip of the click spring, but when the start / stop button 9 is released, the click spring It is returned to its original position (in the direction of the arrow) by the elastic force of 362 and the slope of the wall in the longitudinal direction outside the recess 362a, and is positioned in the recess 362a. Therefore, the operating lever 340 is positioned at a fixed position by the click spring 362 except during operation. When the operating lever 340 returns to the home position, the operating shaft 340a moves in the substantially triangular hole 331 of the hammer 330 and does not engage with the wall in the hole. Is held.
The switch input terminal 340d is separated from the start / stop input pattern 502, and the switch input is turned OFF, but the state of the electronic circuit is not changed, and the chronograph measurement is continued.
[0052]
Next, the stop operation will be described. After starting the chronograph measurement, the start / stop button 9 is pressed and operated. The operating lever 340 is pushed by the start / stop button 9 and rotates counterclockwise. The operating shaft 340a moves in the substantially triangular hole 331 of the hammer 330, but moves without engaging the wall in the hole.
The shaft 340e that engages with the click spring 362 stops over the recess slope from the recess 362a at the tip of the click spring. At this time, the switch input terminal 340d is connected to the start / stop input pattern 502, the stop input is turned ON, the signal to the chronograph motor 201 is stopped, and the chronograph measurement is stopped. When the start / stop button 9 is released, the operating lever 340 is returned to the recess 362a (in the direction of the arrow) at the tip of the click spring by the elastic force of the click spring 362 and the restoring force of the inclined surface, and stops at the position before the button operation. , Retained.
As described above, the start and stop of the chronograph can be repeatedly performed by pressing the start / stop button, and integrated measurement is possible.
[0053]
When the start / stop button 9 is pushed, the resistance force at the moment when the shaft 340e engaged with the click spring 362 of the operating lever 340 gets over the slope of the recess 362a at the tip of the click spring is transmitted to the start / stop button 9. A moderation feeling of the pressing operation can be obtained.
Even when the reset button 10 is pressed, the resistance force at the moment when the operating shaft 321 of the hammer transmission lever 320 moves from the concave portion 361b at the tip of the click spring to the inclined surface portion 361a gets over the mountain between the two concave portions. Therefore, a moderation feeling of the push operation can be obtained.
[0054]
In FIG. 10, the switch input state of the switch input terminal 340d will be described. When the start / stop button 9 is pressed (in the direction of the arrow), the contact surface 340c with the operating lever 340 is pushed, and as described above, the hammer 330, which has been in the zero return state, is moved to the zero release state. Move. At this time, the switch input terminal 340d formed integrally with the operation lever 340 moves from (A) to (B), contacts the start / stop input pattern 502 provided on the circuit board 501, and the start input is turned ON. A drive signal is output to the graph motor 201 to start chronograph measurement. When the pressing operation of the start / stop button 9 is released, the start / stop button 9 is returned to its original position by a button return spring (not shown) provided in the watch case 6. At this time, the operating lever input terminal 340d also returns from the position (B) to the position (A), and the switch input is turned OFF. However, the drive signal continues to be output and chronograph measurement continues.
[0055]
When the start / stop button 9 is pressed again during chronograph measurement, the operating lever 340 is interlocked with the button and the switch input terminal 340d contacts the start / stop input pattern 502 as described above. The input is turned on. At this time, the drive signal from the electronic circuit to the chronograph motor 201 is turned OFF, and the chronograph measurement is stopped. Thereafter, when the pressing operation of the start / stop button 9 is released, the start / stop button 9, the operating lever 340, and the switch input terminal 340d are returned to their original positions, but the state of the chronograph is not changed. As described above, the chronograph is repeatedly started and stopped by repeatedly pressing the start / stop button 9.
[0056]
FIG. 11 shows a state when neither the reset button 10 nor the start / stop button 9 is pressed.
The relative positional relationship among the reset button 10, the transmission lever 310, the hammer transmission lever 320, and the hammer 330 is the same as in FIG.
The actuating lever 340 returns to the recessed portion 362a at the tip of the click spring 362 from the position where the start / stop button 9 is pressed and enters a stable state. The switch input terminal 340d is located away from the start / stop input pattern 502, and the operating shaft 340a moves from one inner wall portion 331a of the substantially triangular hole 331 of the hammer 330 to the opposite wall side. Yes. When the chronograph setting lever 350 is released, the peninsula-shaped tip 340f of the engaged operating lever 340 stops at a position away from the chronograph setting lever 350. The chronograph setting lever 350 is restricted to a position where it does not come into contact with the second CG second intermediate wheel 206 by the peninsula-shaped protrusion 320 d of the hammer transmission lever 320.
Accordingly, since the switch is OFF in each of the start, stop, and reset states except when the switch is input by a button press operation, the current consumption related to the switch ON / OFF can be reduced.
[0057]
Summarizing the above operations, during the start operation, the operating lever 340 is pushed by the pressing operation of the start / stop button 9 and the hammer 330 is moved to a position away from the heart cams 210 and 224. At the same time, the setting of the second CG second intermediate wheel 206 of the chronograph setting lever 350 is released, the switch input terminal 340d is connected to the start / stop input pattern 502, the start switch input is turned ON, and the chronograph measurement is started. The hammer transmission lever 320 is moved to the starting position of the recess 361b at the tip of the click spring and held there. The hammer transmission lever 320 moves the transmission lever 310 to a position where the reset button 10 can be operated. When the operation of the start / stop button 9 is released, the operation lever 340 is returned to the fixed position by the click spring 362 and is held, and the other levers are held in their positions.
[0058]
When the stop operation is performed, the start / stop button 9 is pressed to push the operating lever 340 to the position over the slope of the recess 362a at the tip of the spring to connect the switch input terminal 340d to the start / stop input pattern 502. The stop input is turned ON, the chronograph measurement is stopped, and the chronograph time can be read. At this time, the other levers do not operate. When the operation of the start / stop button 9 is released, the operation lever 340 is returned to and held at the same fixed position as the start operation by the click spring 362.
[0059]
In the zero return operation, when the chronograph is stopped, the reset lever 10 is pressed to push the transmission lever 310, and the hammer transmission lever is moved from the fixed position when the click spring 361 is stopped to the next return. It is moved to the slope portion 361a at the zero time fixed position, the hammer 330 is interlocked, and the heart cams 210 and 224 of the second CG wheel 208 and the minute CG wheel 220 are pressed and returned to zero. At the same time, the chronograph setting lever 350 is pushed and the second CG second intermediate wheel 206 is pressed and set. At this time, the reset switch is turned ON to reset the electronic circuit.
[0060]
According to this embodiment, the following effects can be obtained.
In general, the operation specifications of the chronograph have three operations: start, stop, and zero return operation. In the present embodiment, corresponding to this operation, the main component parts are composed of three parts of a hammer 330, hammer transmission lever 320, and operating lever 340, and the number of parts can be reduced and the chronograph has a simple structure. A watch with a clock can be provided.
In addition, since the positions of the operation lever 340, hammer transmission lever 320, and hammer 330 are regulated and maintained in each of the start, stop, and zero return states, the chronograph operation can be performed reliably.
[0061]
In this embodiment, the transmission lever 310 is disposed between the hammer transmission lever 320 and the reset button 10, and when the reset button 10 is pushed, the transmission lever 310, hammer transmission lever 320, hammer lever 330 is operated. The return zero is performed in conjunction with. Although the position of the reset button 10 is approximately 4 o'clock in the present embodiment, even if the position is moved from the design surface or the like to another position, the configuration after the hammer transmission lever 320 is not changed and the transmission lever 310 is not moved. There is also an advantage that can be accommodated by changing the position and shape. That is, by dividing the hammer transmission lever into a part that contacts the reset button 10 (transmission lever 310) and a part that engages the hammer (330), the layout corresponds to various layouts. It becomes easy and the correspondence range regarding the layout can be widened.
[0062]
In this embodiment, except when the start / stop button 9 is operated, the click transmission spring 362 for positioning the operating lever 340 to a fixed position before the button operation and the hammer transmission lever 320 are returned when the reset button 10 is pressed. A click spring 361 is provided that restricts the position to the zero state and restricts the position of the hammer transmission lever 320 to the zero release state when the start / stop button 9 is operated.
Since such click springs 362 and 361 are provided, the positions of the operating lever 340 and hammer transmission lever 320 can be stably regulated by the concave portion at the tip. In addition, when the button springs over the mountain at the tip of the click spring, the operating force increases to get over the surrounding slope, and the moment you get over it, it instantly moves to the next restriction position. As a result, since the button is not actuated as long as the button is touched, erroneous operation can be prevented.
[0063]
In addition, the click springs 361 and 362 are different in the shape of the concave portion at the tip and the shape of the spring portion, but are integrally formed with the zero return press 360, so the number of parts is reduced, the structure is simplified, and the assembly is improved. There are effects such as. In addition, since the click springs 361 and 362 are formed integrally with the zero return press 360, not only the operation lever 340 and the hammer transmission lever 320 that directly control the position by suppressing the relative position variation, but also the operation lever 340, the positions of the hammer 330 and the chronograph setting lever 350 interlocked with the hammer transmission lever 320 can be accurately maintained, and there is an effect of preventing erroneous operation of the chronograph operation.
[0064]
In the present embodiment, since the slip structure is incorporated in the second CG wheel 208 and the minute CG wheel 220, when the return lever 330 is pressed against the heart cam and zeroing is performed, the heart cam, that is, the second CG wheel 208, the minute CG wheel 220. The chronograph second hand 4 and the chronograph minute hand 5 which are axially fixed to each other are returned to zero, and the other chronograph trains do not rotate. Therefore, the chronograph measurement error due to the start delay can be suppressed at the start without the magnetic phase of the chronograph rotor 204 of the chronograph motor 201 being shifted.
[0065]
In this embodiment, since the switch input terminal 340d configured integrally with the operation lever 340 operated in the order of start and stop is provided as the switch input of the electronic circuit, the movement of the operation lever 340 and the timing of the switch input Can be taken easily.
Further, since the operation lever 340 is returned to a fixed position by the positioning member after the start / stop operation, the switch input terminal 340d transmits the switch input to the electronic circuit, and then at a position away from the start / stop input pattern 502 of the electronic circuit. Retained. Therefore, no constant current is generated due to switch input, and power consumption can be reduced. Further, the switch input terminal 340d has a degree of freedom in selecting the position of the operation lever 340, and can be stored in the movement, which contributes to a compact timepiece configuration.
[0066]
In the present embodiment, since the chronograph setting lever 350 is provided, even when the slip torque of the second CG wheel 208 and the minute CG wheel 220 becomes larger than the load of the chronograph wheel train, the slip function can be surely activated. It is possible to prevent rotation to the chronograph wheel train when returning to zero, and to eliminate measurement errors when the chronograph is started. In addition, the timing at the time of return to zero is preferably performed in the order of reset switch input, correction, and return to zero. However, the hammer transmission lever 320 operates the chronograph setting lever 350 and the hammer lever 330 to set the correction, Since the zero return operation is linked, there is an effect that it is easy to set the optimum timing.
[0067]
In this embodiment, the chronograph setting lever 350 is engaged with the operating lever 340 when the start / stop button 9 is pressed, and the chronograph wheel train is released when the start / stop button 9 is operated. ing.
When starting the chronograph, it is necessary that the chronograph setting lever 350 is released from the gear of the chronograph wheel train before the start switch is input. The optimum timing for chronograph start is the order of zero return release or regulation release, and start switch input. The operation lever 340 that inputs the start switch and cancels the regulation and the chronograph regulation lever 350 are directly linked to each other, so that the timing can be easily obtained.
[0068]
It should be noted that the present invention is not limited to the above-described embodiment, but includes modifications and improvements as long as the object of the present invention can be achieved.
For example, in the embodiment, the transmission lever 310 is provided between the reset button 10 and the hammer transmission lever 320. However, depending on the layout of the reset button 10, the hammer transmission lever 320 is directly pushed by the reset button 10. May be. Further, instead of one transmission lever 310, a plurality of levers may be combined such that another lever is interposed between a lever that contacts the reset button 10 and a lever that engages the hammer 330.
[0069]
In the present embodiment, the slip structure of the second CG wheel 208 and the minute CG wheel 220 is obtained by pressing the gear with a slip spring to obtain the slip torque, but the same effect can be obtained even if an elastic portion is provided on the gear itself. Moreover, although the slip mechanism is provided in the second and minute CG wheels, it may be provided in a part of another chronograph wheel train.
The slip mechanism is not necessarily provided. When the slip structure is not provided, when the chronograph rotor 204 is rotated by operation and the magnetic phase shifts, the load on the electronic circuit increases, but the electronic circuit detects the magnetic phase with the first drive signal. There is also a means for outputting an optimum drive signal.
[0070]
Further, in this embodiment, two CG vehicles, the second CG wheel 208 and the minute CG wheel 220, are mounted to display the chronograph measurement, but other chronograph times such as the hour CG wheel are displayed. A CG vehicle may be added, and the same effect can be obtained with a single second CG vehicle.
[0071]
The actuating lever positioning member and the hammer transmission lever positioning member of the present embodiment are click springs having an elastic portion and a restricting portion. However, the same effect can be obtained by combining a plurality of levers and springs.
In the present embodiment, the two positioning members are integrally formed with the nulling presser 360, but may be formed as a single member for positioning or other members other than the nulling presser. is there.
[0072]
In this embodiment, the start / stop button is also used, but the start button and the stop button may be provided separately.
Further, the switch input spring 340d is not limited to being integrally formed with the operation lever 340. For example, if it is set so as to be linked to the operation of the start / stop button, the switch input spring can be provided separately from the operating lever.
[0073]
The chronograph setting lever of this embodiment sets the second CG second intermediate wheel 206, but may be another gear of the chronograph wheel train. However, since the chronograph wheel train is a reduction gear train from the chronograph motor, a gear close to the chronograph wheel rotor 204 is preferable in order to reduce the setting torque.
The chronograph setting lever engages with the hammer transmission lever to adjust, and engages with the actuating lever to release the setting. However, the setting is released with another member linked to the start / stop button operation, and reset. It is also possible to use other members that are linked to the button operation.
[0074]
In the present embodiment, an electronic timepiece has been described as an example. However, in the present invention, the electronic timepiece may be employed in a chronograph mechanism of a mainspring drive mechanical timepiece.
[0075]
【The invention's effect】
According to the present invention as described above, the mechanical zero return structure of the chronograph needle can be realized with a small number of parts, the structure can be simplified, the assemblability can be improved, and there is a sense of moderation, which can be operated reliably. In addition, there is an effect of preventing malfunction.
[Brief description of the drawings]
FIG. 1 is a table external view of a chronograph timepiece according to an embodiment of the present invention.
FIG. 2 is an overall perspective view of the main part of the movement of the present invention.
3 is an enlarged perspective view of a main part of the chronograph wheel train of FIG. 2. FIG.
FIG. 4 is a sectional view of a second CG wheel and a minute CG wheel.
FIG. 5 is a plan view of the main part at the time of return to zero.
6 is a perspective view of main components shown in FIG.
FIG. 7 is a cross-sectional view when a reset button is operated.
8 is a side view seen from the button side of FIG. 7. FIG.
FIG. 9 is a plan view of the main part at the start / stop.
FIG. 10 is a cross-sectional view when a start / stop button is operated.
FIG. 11 is a plan view of a main part before button operation.
[Explanation of symbols]
1 ... Basic clock hour hand, 2 ... Basic clock minute hand, 3 ... Basic clock second hand, 4 ... Ronograph second hand, 5 ... Chronograph minute hand, 6 ... Case, 7 ... Dial, 8 ... Crown, 9 ... Start / Stop button, DESCRIPTION OF SYMBOLS 10 ... Reset button, 201 ... Chronograph motor, 202 ... Chronograph coil, 203 ... Chronograph stator, 204 ... Chronograph rotor, 205 ... Second CG third intermediate wheel, 206 ... Second CG second intermediate wheel, 207 ... Second CG first intermediate wheel, 208 ... second CG wheel, 209 ... second CG gear, 210 ... second heart cam, 211 ... second CG axle, 212 ... slip spring, 213 ... slip spring holding seat, 220 ... minute CG wheel, 221 ... minute CG first intermediate wheel, 222 ... minute CG second intermediate wheel, 223 ... minute CG gear, 224 ... minute heart cam, 225 ... minute CG axle, 310 ... transmission lever 320 ... hammer transmission lever, hammer operating lever ... 330, 350 ... operating lever, 360 ... zero return press, 361 ... click spring (branch needle transmission lever side), 362 ... click spring (operating lever side), 400 ... ground plate, 501 ... Circuit board, 502 ... Start / stop input pattern, 600 ... Circuit holder, 700 ... Circuit seat, 701 ... Reset terminal.

Claims (10)

A chronograph wheel holding a chronograph hand for displaying the chronograph time and having a heart cam;
A chronograph wheel train for transmitting driving force from a driving source to the chronograph wheel;
A hammer returning to a position where the heart cam is pressed against and a position apart from the heart cam;
A first external operation member;
When the hammer is in pressure contact with the heart cam, the hammer is moved to a position away from the heart cam in conjunction with the pressing operation of the first external operation member, and the first external An operating lever that is positioned at a fixed position except when operating the operating member;
A second external operation member;
A hammer transmission lever that regulates the hammer in a position in pressure contact with the heart cam in conjunction with the pressing operation of the second external operation member;
An operation lever positioning member engaged with the operation lever;
A positioning member for a hammer transmission lever that engages with the hammer transmission lever;
The positioning member for the operating lever is
An elastic portion that can be elastically deformed by a pressing force when operating the first external operation member;
A regulating portion that positions the operating lever at a fixed position by using an elastic force of the elastic portion except when the first external operation member is operated,
The hammer transmission lever positioning member is:
An elastic portion that can be elastically deformed by any pressing force of the pressing force when operating the first external operation member and the pressing force when operating the second external operation member;
Using the elastic force of the elastic portion, a restriction portion that positions the hammer transmission lever at a position when the hammer is separated from the heart cam and a position when the heart cam is pressed,
A watch with a chronograph. The chronograph timepiece according to claim 1,
The hammer transmission lever comprises a first hammer transmission lever and a second hammer transmission lever;
Each hammer transmission lever is provided with a rotation shaft in the middle part and each end part is rotatably arranged, and one end part is connected to each other so as to be rotatable and slidable,
The other end of the first hammer transmission lever is disposed so as to be in contact with the second external operation member,
A timepiece with chronograph, wherein the other end of the second hammer transmission lever is provided so as to be able to contact the hammer. The chronograph timepiece according to claim 1 or 2,
The operation lever positioning member and the hammer transmission lever positioning member are formed at different positions of the same member. In the timepiece with a chronograph according to any one of claims 1 to 3,
When the hammer is in pressure contact with the heart cam, the chronograph hand starts when the hammer is released from the heart cam by pressing the first external operation member interlocked with the operating lever.
When the hammer is separated from the heart cam and the chronograph hand is operating, pressing the first external operation member stops the chronograph hand,
When the hammer is separated from the heart cam and the chronograph hand is stopped, pressing the first external operation member starts the chronograph hand,
A chronograph-equipped timepiece wherein the chronograph hand returns to zero when the second external operation member is pressed when the hammer is away from the heart cam. The chronograph timepiece according to claim 4,
The operating lever includes a switch input spring that is input by a pressing operation of the first external operation member,
A chronograph-equipped timepiece, wherein start and stop operations of the chronograph hands are controlled by an input of the switch input spring. In the timepiece with a chronograph according to any one of claims 1 to 5,
A chronograph timepiece, wherein the chronograph wheel is composed of a shaft portion having a heart cam and a gear portion meshing with another chronograph wheel train and slip-engaging with the shaft portion. In the timepiece with a chronograph according to any one of claims 1 to 6,
A chronograph timepiece comprising a chronograph setting lever for setting any one gear between a driving source of a chronograph wheel train and a chronograph wheel when the chronograph wheel returns to zero. The chronograph timepiece according to claim 7,
The chronograph setting lever engages with the hammer transmission lever and presses and adjusts one of the gears of the chronograph wheel train in conjunction with the pressing operation of the second external operation member. Clock with chronograph. In the timepiece with a chronograph according to claim 7 and claim 8,
A chronograph timepiece, wherein the chronograph setting lever engages with the operating lever and releases the setting of the chronograph wheel train in conjunction with a pressing operation of the first external operation member. In the timepiece with a chronograph according to any one of claims 1 to 9,
The hammer is provided with a pressure contact portion that can be pressure-contacted with the heart cam, first and second holes, and a rotation shaft,
The actuating lever includes one end contacting the first external operating member, the other end having an actuating shaft engaged with the first hole of the hammer, and a rotation provided between the ends. With a moving shaft,
The hammer transmission lever includes one end that contacts the second external operation member, a shaft member that engages with the second hole of the hammer, and a rotation shaft provided between the ends. With
When the hammer is pressing the heart cam, the first hole of the hammer is when the operating lever is rotated in conjunction with the pushing operation of the first external operation member. When the operating shaft comes into contact with the inner wall of the hole to move the hammer, and the hammer is separated from the heart cam, the operating lever pushes the first external operating member. When the operation shaft is rotated in conjunction with, it is formed in a shape that can freely move relative to the hammer without contacting the inner wall of the hole,
When the hammer is in pressure contact with the heart cam, the second hole of the hammer has an inner wall of the hole that rotates with the hammer transmission lever. When the shaft member is pushed and the hammer is separated from the heart cam, the shaft member of the hammer transmission lever abuts against the inner wall of the hole and presses against the heart cam of the hammer. A timepiece with a chronograph, which is formed in a shape capable of restricting movement in a moving direction.

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