JP2020060592A - Movement of electronic clock - Google Patents

Abstract

To provide a movement of an electronic clock capable of enhancing utilization efficiency of a space.SOLUTION: A movement of an electronic clock includes an antenna for receiving a radio wave and a buzzer coil. The antenna is a rectangular patch antenna, and the buzzer coil is arranged between the antenna and an outer peripheral contour of a movement 3.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an electronic timepiece movement.

  The electronic timepiece drives a time display hands and the like with a step motor. When a shock is input to the electronic timepiece, a large moment acts on the hands. The pointer of the electronic timepiece is connected to the rotor of the step motor via the train wheel, but since the rotor is only held in place by the holding force of the step motor, the moment that exceeds the holding force is the pointer. It is input from and rotates, and the pointer is displaced.

It is possible to prevent displacement of the pointer due to impact input by increasing the holding force of the step motor, but if the holding force is increased, it is necessary to increase the electric power required to rotate the rotor. is there. Therefore, the power consumption of the step motor increases, which is not preferable from the viewpoint of energy saving.
In particular, if the holding force of the step motor for the second hand, which is frequently driven, is increased, the increase in power consumption becomes a more important problem.

  Therefore, when a shock is input, the pointer is moved, which detects the counter electromotive force generated in the step motor when the rotor is rotated, thereby detecting the shock input and detecting the shock input. In this case, a shock detection function is proposed in which drive control for braking the rotor is performed to prevent displacement of the pointer (see, for example, Patent Document 1).

JP, 2005-172677, A

  An object of the present invention is to provide a movement of an electronic timepiece that can improve space utilization efficiency.

  The present invention includes an antenna for receiving radio waves and a buzzer coil, wherein the antenna is a rectangular patch antenna, and the buzzer coil is a movement of an electronic timepiece arranged between the antenna and the outer peripheral contour of the movement. is there.

  According to the movement of the electronic timepiece of the invention, the space utilization efficiency can be improved.

FIG. 3 is a perspective view showing a radio-controlled timepiece which is an embodiment of an electronic timepiece having the movement of the electronic timepiece according to the invention. It is the figure which looked at the electric wave correction timepiece shown in FIG. 1 from the dial side. It is a figure which shows arrangement | positioning of four step motors in a movement.

Embodiments of the electronic timepiece movement according to the present invention will be described below with reference to the drawings.
<Structure of radio-controlled watch>
FIG. 1 shows a radio-controlled timepiece 1 which is an embodiment of an electronic timepiece having an electronic timepiece movement according to the present invention, in which a case 2 represented by an alternate long and two short dashes line is virtually transparent from the case back side. It is a perspective view showing the state where the movement 3 represented by is visible. The upper part of FIG. 1 is at 12 o'clock and the left is at 3 o'clock. FIG. 2 is a view of the radio-controlled timepiece 1 shown in FIG. 1 as seen from the dial 4 side, and illustration of exterior parts such as the case 2 is omitted.

As shown in FIG. 1, the radio-controlled timepiece 1 has a movement 3 housed inside a metal case 2 having conductivity. The radio-controlled timepiece 1 has a function of receiving a radio wave including time information (for example, a GPS signal including time information transmitted from a GPS satellite) and automatically correcting a time display pointer to a correct position.
As shown in FIG. 2, the radio-controlled timepiece 1 is provided with an hour hand 5a, a minute hand 5b, and a second hand 5c, which are examples of hands that rotate clockwise around the center of the dial 4. Further, a dual minute hour lower case plate 4a for indicating the hour and minute different from the time indicated by the hour hand 5a and the minute hand 5b by the 24-hour display is formed in the portion of the dial plate 4 in the 6 o'clock direction. The radio-controlled timepiece 1 is provided with a dual hour hand 5d and a dual minute hand 5e corresponding to the dual minute hour lower case plate 4a.

In addition, the day of the week (S, M, T, W, T, F, S) is indicated in the 9 o'clock direction of the dial 4, and summer time (SMT) is turned on (ON) and off (OFF). The function display small letter plate 4b is formed to indicate the selected state of the battery and the remaining charge of the battery. Corresponding to this function display small letter board 4b, the radio-controlled timepiece 1 is provided with a function display hand 5f.
Further, a function switching lower case plate 4c for switching the displayed functions of the hour hand 5a, the minute hand 5b, the second hand 5c, the dual hour hand 5d, the dual minute hand 5e and the function display hand 5f is formed in the part of the dial 4 at the 3 o'clock position. ing. Corresponding to the function switching small letter board 4c, the radio-controlled timepiece 1 is provided with a function switching hand 5g.

  The hour hand 5a, the minute hand 5b, the second hand 5c, the dual hour hand 5d, the dual minute hand 5e, and the function display hand 5f are step motors 31, 32, 33, 34 provided in the movement 3 as described later (see FIG. 3, which will be described later). ), The function switching needle 5g is rotationally driven by manually operating the crown (not shown).

  In a portion of the dial 4 between the 4 o'clock direction and the 5 o'clock direction, the date character (“7” in the example of FIG. 3) described on the date plate arranged on the back side of the dial 4 6 The date window 4d for exposing the is opened.

<Movement configuration>
FIG. 3 is a diagram showing the arrangement of the four step motors 31, 32, 33, 34 in the movement 3, as viewed from the back side of FIG.
The movement 3 is an embodiment of the movement of the electronic timepiece according to the invention. As shown in FIG. 3, the movement 3 includes four step motors 31, 32, 33, 34.

The step motor 31 arranged corresponding to the direction between 3 o'clock and 4 o'clock on the dial 4 (see FIG. 2) of the radio-controlled timepiece 1 is a step hand motor for rotating the second hand 5c. Hereinafter, this step motor 31 will be referred to as a second hand step motor 31. The second hand step motor 31 is driven at a cycle (frequency) once per second.
The step motor 32 arranged corresponding to the direction from 8 o'clock to 9 o'clock of the dial 4 is a step motor for the minute hand for rotating the hour hand 5a and the minute hand 5b. Hereinafter, the step motor 32 will be referred to as the minute hand step motor 32. The minute hand step motor 32 is driven at a cycle (frequency) once every 10 seconds. The minute hand step motor 32 has two coils 32a and 32b.

The step motor 33 arranged corresponding to the 6 o'clock direction of the dial 4 is a dual minute hand step motor for rotating the dual hour hand 5d and the dual minute hand 5e. Hereinafter, this step motor 33 will be referred to as a dual minute hand step motor 33. The dual minute hand step motor 33 is driven at a cycle (frequency) once a minute.
The step motor 34 arranged corresponding to the direction from 9 o'clock to 10 o'clock of the dial 4 is a step display motor for rotating the function display hand 5f. Hereinafter, this step motor 34 is referred to as a function indicating needle step motor 34. The function indicating needle stepping motor 34 is driven at a cycle (frequency) once a day for displaying the day of the week. When using another function displayed by the function display hand 5f, it is also driven when using that function.

The second hand step motor 31 and the minute hand step motor 32 have an impact detection function for controlling the drive by detecting an impact input to the step motors 31 and 32, respectively.
Specifically, the shock detection function is a function to prevent the pointer from moving due to the shock when a shock is input by dropping the radio-controlled timepiece 1 or the like. The impact detection function, for example, detects the movement of the rotor of the step motor that drives the pointer when the pointer moves due to the input of impact by detecting the counter electromotive force, and when the counter electromotive force is detected, the step detection is performed. It is realized by controlling the drive so as to brake the rotor of the motor.

  Therefore, each of the stepper motors to which the shock detection function is added is driven so as to brake the rotor when the shock input is detected and the shock detection circuit that detects the shock input by detecting the back electromotive force, for example. And a control circuit for controlling. In the present embodiment, the step motor 31 for the second hand and the step motor 32 for the minute hand are controlled by the IC 39 having the functions of the impact detection circuit and the control circuit, and the above-mentioned impact detection function is added.

The movement 3 includes a main plate 7, a train wheel mechanism (not shown), a train wheel receiver, a circuit board on which circuits such as an IC 39 are formed, a circuit pressing plate, two magnetic-proof plates, an antenna for receiving radio waves, and a buzzer coil. And so on.
The train wheel mechanism is rotatably supported by the main plate 7 and the train wheel receiver, and has pointers corresponding to the step motors 31 to 34 (second hand 5c, minute hand 5b, hour hand 5a, dual hour hand 5d, dual minute hand 5e, function). It is connected to the display hand 5f).
The train wheel mechanism is disposed in a train wheel recess 7 a or the like formed by denting the main plate 7 to dispose the train wheel mechanism. A part of the wheel train recess 7 a is formed between the minute hand step motor 32 and the second hand step motor 31. Therefore, a part of the train wheel mechanism is arranged between the step motor 32 for the minute hand and the step motor 31 for the second hand.

The radio wave receiving antenna is, for example, a rectangular patch antenna in plan view. This antenna is arranged in a concave portion 7b for an antenna, etc., which is formed by recessing the antenna on the base plate 7.
The buzzer coil is sounded when the alarm (ALM) displayed on the function switching lower case plate 4c is set. This buzzer coil is arranged in the buzzer coil concave portion 7c or the like which is formed to be concave in order to arrange the buzzer coil in the main plate 7. The buzzer coil recess 7c is formed in a space around the antenna recess 7b.

Here, the distance between the minute hand step motor 32 and the second hand step motor 31 is L1, the distance between the minute hand step motor 32 and the dual minute hand step motor 33 is L2, and the minute hand step motor. Letting L3 be the distance between 32 and the step motor 34 for function indicating hands, these distances L1, L2, L3 have the following magnitude relationship.
L1> L2, L3
That is, the second hand step motor 31 is arranged at the farthest position as viewed from the minute hand step motor 32, and the dual minute hand step motor 33 and the function display hand step motor 34 are arranged at the next farthest positions. There is.

<Action of movement>
According to the radio-controlled timepiece 1 and the movement 3 of the present embodiment configured as described above, the driving frequency of the other minute stepping motors 31, 33, 34 from the minute hour hand stepping motor 32 to which the impact detection function is added. Is arranged at the farthest position (position of distance L1).

The minute hand step motor 32 is unlikely to be affected by the leakage magnetism during driving from the second hand step motor 31 arranged at the farthest position. Therefore, the minute hand step motor 32 normally operates the impact detection function without switching the impact detection function added to the minute hand step motor 32 to the non-operating state each time the second hand step motor 31 is driven. Can be made.
As a result, the radio-controlled timepiece 1 and the movement 3 according to the present embodiment can operate the shock detection function added to the minute hand step motor 32 without frequently stopping, and the shock detection function is in a non-operating state. The time can be shortened.

In the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the other step motors 31, 33, 34 except for the step motor 32 for the minute hand with the impact detection function are arranged in descending order of driving frequency (for the second hand). The step motor 31, the dual minute hand step motor 33, and the function indicating hand step motor 34 are arranged in this order), that is, in the descending order of the frequency of occurrence of leakage magnetism, the farthest from the minute hour hand step motor 32 to which the impact detection function is added. By arranging at the position (distance L1>L2> L3), the frequency of stopping the impact detection function of the minute hand step motor 32 can be minimized.
According to the radio-controlled timepiece 1 and the movement 3 of the present embodiment, it is not necessary to stop the impact detection function in the optimum case, and it is not necessary to switch the impact detection function between the operating state and the non-operating state.

In the radio-controlled timepiece 1 and the movement 3, radio waves from an antenna such as a train wheel mechanism are provided between the step motor 32 for the minute hand and the step motor 31 for the second hand with the highest driving frequency (recess 7a for the train wheel). It is preferable to dispose only the operation member that does not affect reception of the signal and not dispose the step motor.
However, it is not completely excluded to dispose another step motor between the minute hand step motor 32 and the second hand step motor 31 having the highest driving frequency. In this way, when arranging other step motors, it is preferable to arrange the step motors 33 and 34 that have a lower drive frequency than others.

In addition to the train wheel mechanism, an operating member such as a radio wave receiving antenna may be arranged between the minute hand step motor 32 and the second hand step motor 31 having the highest driving frequency. When arranging the antenna, the antenna concave portion 7b for arranging the antenna may be formed on the main plate 7 between the minute hand step motor 32 and the second hand step motor 31 having the highest driving frequency.
With an antenna disposed between the minute hand step motor 32 and the second hand step motor 31 having the highest driving frequency, when the radio wave is received by the antenna, the second hand step motor 31 and the minute hand step motor 32 are It is preferable to stop the driving.

The radio-controlled timepiece 1 and the movement 3 of this embodiment include two step motors (second hand step motor 31, minute hour hand step motor 32) to which an impact detection function is added, and viewed from the minute hour hand step motor 32. The step motor 31 for the second hand is arranged farther than the other step motors 33 and 34. Therefore, it is possible to prevent mutual interference of the impact detection functions of the two step motors 31 and 32.
Further, the radio-controlled timepiece 1 and the movement 3 of the present embodiment can also prevent the influence of the leakage magnetism of the pulses output by the step motors 31 and 32 to which the shock detection function is added during braking.

  In the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the impact detection function is added to the second hand step motor 31 and the minute hand step motor 32, and therefore the hour hand 5a and the minute hand 5b for indicating the time. It is possible to prevent all the positional deviations of the second hand 5c without increasing the power consumption.

In the radio-controlled timepiece 1 and the movement 3 of this embodiment, the minute hour step motor 32 has two coils 32a and 32b. By controlling the two coils 32a and 32b to drive one rotor, it is possible to rotate the rotor in the forward rotation direction (clockwise direction) and in the reverse rotation direction (counterclockwise direction). , The rotation speed can be the same.
Therefore, for example, in order to adjust the time difference between cities in the world, the speed of moving the minute hand 5b and the hour hand 5a can be made equal by the step motor 32 for the minute hand, and the operability can be improved. it can.

In the radio-controlled timepiece 1 and the movement 3 of this embodiment, the step motor 31 for the second hand is arranged corresponding to the direction between 3 o'clock and 4 o'clock of the dial 4, and the step motor 32 for the hour hand is 8 o'clock of the dial 4. It is arranged corresponding to the direction from 9 o'clock to 9 o'clock.
Generally, since the hands are not arranged at the position near 4 o'clock or the position near 8 o'clock of the dial 4, a train wheel mechanism connected to the hands is not arranged and a dead space is likely to be formed.

On the other hand, in the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the second hand step motor 31 is arranged at a position near 4 o'clock of the dial plate 4 which is prone to dead space, and the dial plate which is prone to dead space. The minute hand step motor 32 is arranged at a position near 4 o'clock of 4 o'clock.
Therefore, the radio-controlled timepiece 1 and the movement 3 of this embodiment can effectively use the dead space.

Further, in the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the positions near 4 o'clock and the position near 8 o'clock at which the two step motors 31 and 32 having the shock detection function are arranged are the movements of the movement 3. The positions are almost diagonal to each other with the center in between.
Therefore, according to the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the two step motors 31 and 32 having the shock detection function are arranged apart from each other in the limited space in the movement 3. You can

The radio-controlled timepiece 1 and the movement 3 of the present embodiment have a combination of two step motors 31 and 32 having an impact detection function, that is, a position near 4 o'clock and a position near 8 o'clock. The arrangement of the two step motors to which the impact detection function is added in the electronic timepiece and the movement of the electronic timepiece according to the present invention is not limited to the combination of the positions in this embodiment.
Therefore, in the radio-controlled timepiece 1 and the movement 3 according to the present embodiment, the two step motors 31 and 32 having the shock detection function are arranged at a position near 12 o'clock by disposing an antenna or the like at another position. The arrangement may be a combination of positions around 6 o'clock. Further, it is also possible to adopt an arrangement in which other positions are combined.

  In the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the buzzer coil concave portion 7c is formed around the antenna concave portion 7b of the main plate 7, so that the buzzer coil is arranged around the antenna. Since the antenna is a rectangular patch antenna and the movement 3 has a circular outer peripheral contour, a dead space is formed around the antenna. Since the buzzer coil is arranged in the dead space formed around the antenna, the radio-controlled timepiece 1 and the movement 3 can improve the utilization efficiency of the space inside the movement 3.

  The radio-controlled timepiece 1 and the movement 3 according to the present embodiment have two step motors with an impact detection function, but are not limited to having two step motors with an impact detection function, and two or more step motors. Anything will do.

In the radio-controlled timepiece 1 and the movement 3 of the present embodiment, the second hand step motor 31 also has an impact detection function. When viewed from the step motor 31 for the second hand, the step motor arranged at the farthest position is the step motor 34 for the function display hand.
However, the step motor 34 for the function indicating hands has an extremely low drive frequency as compared with the remaining other step motors (the step motor 32 for the minute hand and the step motor 33 for the dual minute hand), and the step motor 34 that practically does not operate. It can be said that it is a motor.

Therefore, when viewed from the step motor 31 for the second hand, it practically hardly operates from other plural step motors (step motor 32 for minute hour hand, step motor 33 for dual minute hand, step motor 34 for function indicating hand). The function indicating hand stepping motor 34 may be excluded from the objects to be arranged at a position far from the second hand stepping motor 31.
As a result, when viewed from the second hand step motor 31, the radio-controlled timepiece 1 and the movement 3 of the present embodiment include only the minute hand step motor 32 and the dual minute hand step motor 33 as the other step motors. As a result, the minute hand step motor 32 is arranged at the farthest position from the second hand step motor 31.

Further, the step motor in the movement of the electronic timepiece according to the invention can be limited to only the step motor driven at a constant cycle.
That is, since the step motor 31 for the second hand, the step motor 32 for the minute hand and the step motor 33 for the dual minute hand in the radio-controlled timepiece 1 and the movement 3 of the present embodiment operate at a constant cycle, the electronic timepiece of the present invention It is an example of a step motor in a movement.

On the other hand, since the step motor 34 for function indicating hands in the radio-controlled timepiece 1 and the movement 3 of the present embodiment is driven at an indefinite cycle in correspondence with irregular operation, the step motor of the step motor in the movement of the electronic timepiece of the present invention can be used. It can be excluded.
The step motor corresponding to such irregular operation corresponds to the step motor for the chronograph display hands and the function operated by the user's operation, in addition to the step motor 34 for the function display hands described above. It is possible to apply a step motor or the like.

  In the radio-controlled timepiece 1 and the movement 3 of this embodiment, the second hand step motor 31 that drives the second hand 5c and the minute hand step motor 32 that drives the minute hand 5b and the hour hand 5a are provided with an impact detection function. However, the movement of the electronic timepiece of the invention is not limited to this embodiment.

  That is, the radio-controlled timepiece 1 and the movement 3 are replaced with, for example, the step motor 31 for the second hand and the step motor 32 for the minute hour hand, as a single step motor for driving the second hand 5c and the minute hand 5b, a step motor for the second hand and an hour hand. An hour hand step motor may be provided as a step motor that drives 5a, and an impact detection function may be added to each of the second minute hand step motor and the hour hand step motor. In this case, the second minute hand step motor may have two coils, like the minute hand step motor 32.

  Further, the radio-controlled timepiece 1 and the movement 3 are replaced with, for example, the step motor 31 for the second hand and the step motor 32 for the minute hour hand, as a step motor for driving the second hand 5c, a step motor for the second hand and a step motor for driving the minute hand 5b. As a step motor for driving the hour hand 5a and a step motor for driving the hour hand 5a, and an impact detection function is added to each of the step motor for the second hand, the step motor for the minute hand and the step motor for the hour hand. Good.

  Since the electronic timepiece has a main function of displaying time information, the time information is displayed with a larger pointer than a pointer for displaying other additional functions. The pointer that displays the time information is driven more frequently than the pointer that displays other additional functions. Therefore, in the movement of the electronic timepiece of the invention, the impact detection function is added to the step motor that drives the hour hand, the minute hand, or the second hand for displaying the time information, thereby preventing or suppressing the position shift of the large, easily visible hands. What you can do is a very important advantage.

1 radio-controlled timepiece 3 movement 4 dial 4a dual minute hour small letter board 4b function display small letter board 4c function switching small letter board 5a hour hand 5b minute hand 5c second hand 5d dual hour hand 5e dual minute hand 5f function display hand 5g function switching hand 31 second hand step motor 32 minute hand step motor 33 dual minute hand step motor 34 function display hand step motor L1, L2, L3 distance

Claims (2)

Equipped with an antenna for receiving radio waves and a buzzer coil,
The antenna is a rectangular patch antenna,
The buzzer coil is a movement of an electronic timepiece, which is arranged between the antenna and the outer peripheral contour of the movement. On the side surface of the antenna, only the operation member that does not affect reception of radio waves is arranged,
The movement of the electronic timepiece according to claim 1, wherein the operation member is a train wheel mechanism.