JP4827561B2 - Pointer-type radio correction clock - Google Patents

Description

  The present invention relates to a pointer-type radio-controlled timepiece, and in particular, to an improvement in the arrangement relationship between an antenna and a plurality of step motors.

  2. Description of the Related Art Conventionally, a timepiece in which hands such as an hour hand, a minute hand, a second hand, and a date plate indicating a date are driven by a step motor is known.

  In recent years, so-called radio-controlled timepieces that receive a standard time radio wave and based on the radio wave, a step motor corrects the indicated position of a pointer such as a second hand to a correct indicated position have become widespread.

Here, radio-controlled timepieces are required to have very strict accuracy with respect to instructions such as time, and in order to meet this requirement and reduce the time required for correction operations such as instruction time, In some cases, a plurality of step motors are provided inside a single radio-controlled timepiece, for example, a step motor is provided corresponding to (Patent Document 1).
JP 2005-024319 A

  By the way, when a timepiece is placed in the vicinity of an electric product such as a television, the step motor inside the timepiece may be affected by external magnetism emitted from a magnet built in the electric product.

  Therefore, in order to prevent the step motor from being affected by this, it is conceivable to arrange a magnetic-resistant plate that absorbs magnetism inside the timepiece.

  However, when a radio wave (electromagnetic wave) is received by a built-in antenna like a radio-controlled timepiece, a radio-resistant plate absorbs the radio wave to be received by the antenna, which may cause a decrease in reception sensitivity.

  The present invention has been made in view of the above circumstances, and at least a part of a plurality of built-in step motors is affected by external magnetism while preventing the reception sensitivity of the built-in antenna from decreasing. An object of the present invention is to provide a pointer-type radio-controlled timepiece that can prevent or suppress the above.

  The pointer-type radio-controlled timepiece according to the present invention is configured such that when a timepiece is divided into two regions by a virtual vertical plane including a support shaft of the pointer, at least a part of a plurality of step motors is a magnetic-resistant plate (magnetic shield plate). The step motor covered with the magnetic-resistant plate is arranged in a region different from the antenna, thereby preventing a decrease in the reception sensitivity of the antenna, and at least a part of the step motor is affected by external magnetism. Is to prevent or suppress this.

  That is, the pointer-type radio wave correction timepiece according to the present invention is a pointer-type radio wave correction timepiece having an antenna for receiving radio waves and a plurality of step motors for driving the hands, by means of a virtual vertical plane including a shaft of the pointer. The antenna is disposed in one of the two divided areas, and at least one of the plurality of step motors is disposed in the other area, as viewed from the direction along the support shaft. And a magnetic-resistant plate disposed so as to cover at least all of the step motors disposed in the other region and not to cover the antenna.

  Here, the “pointer” is not only a time indication hand such as a second hand, a minute hand, an hour hand, etc., but, for example, in a pointer type radio wave correction watch with a calendar function, a date plate (ring-shaped with a date written) Plate) is included as one of the guidelines.

  The “guide shaft” is an axis provided at the center of rotation of the pointer. Further, “viewed from the direction along the support shaft” means to view from the dial side or back cover side of the timepiece along the line of sight along the thickness direction of the timepiece.

  Therefore, “covering the step motor when viewed from the direction along the support shaft” means that the step motor is overlapped with the magnetic plate in the thickness direction of the watch, that is, when viewed from the dial side, or When viewed from the lid side, this means that the step motor is on the back side of the magnetic-resistant plate and is hidden by the magnetic-resistant plate.

  According to the pointer-type radio-controlled timepiece according to the present invention configured as described above, at least one of the plurality of stepping motors is covered with the magnetic-resistant plate, so that the influence from external magnetism is prevented or suppressed. be able to.

  On the other hand, the one area where the antenna is arranged is different from the area where the step motor covered with the magnetic-resistant plate is arranged among the two areas divided by the virtual vertical plane including the support shaft of the pointer. Therefore, the antenna is placed far away from the magnetic-resistant plate that absorbs radio waves, and the receiving sensitivity of the antenna is not lowered.

  Therefore, the pointer-type radio-controlled timepiece according to the present invention prevents at least a part of the built-in step motors from being affected by external magnetism while preventing the reception sensitivity of the built-in antenna from deteriorating. Can be prevented or suppressed.

  Note that the step motors arranged in the other region different from the antenna arrangement region may be only some of the step motors or all of the step motors.

  In a pointer-type radio-controlled timepiece having a configuration in which only some step motors are arranged in the other area, the remaining step motors are arranged in one area where the antenna is arranged. The step motor arranged in one region may have a high anti-magnetic performance, or the step motor itself may not have high anti-magnetic performance but is provided with a means for compensating an appropriate operation. That's fine.

  As a means for compensating for an appropriate operation, a pointer position detecting means for detecting a moving position of the pointer by detecting a displacement position of a gear train mechanism that connects the step motor and a pointer driven by the step motor; In addition, it is possible to apply a device including a pointer position correcting unit that corrects the hand movement position of the pointer in accordance with the displacement position detected by the pointer position detecting unit.

  According to the pointer-type radio-controlled timepiece according to the present invention, at least a part of the plurality of built-in step motors is affected by external magnetism while preventing the reception sensitivity of the built-in antenna from decreasing. Can be prevented or suppressed.

Hereinafter, specific embodiments of a pointer-type radio-controlled timepiece according to the present invention will be described with reference to the drawings.
Example 1
FIG. 1 is a schematic view of the internal configuration of a pointer-type radio-controlled wristwatch 10 according to an embodiment of the present invention as viewed from the back cover side.

  The wristwatch 10 shown in the figure includes an antenna 13 for receiving standard time radio waves, a first step motor 14 for driving the second and minute hands, a second step motor 15 for driving the hour hand, And a third step motor 16 that drives the date plate), and is divided by a virtual vertical plane (a plane perpendicular to the paper surface of the drawing) P including the support shaft 17 of these hands (second hand, minute hand, hour hand, date wheel). Of the two regions R1 and R2, the antenna 13 is disposed in the first region (one region) R1, and all of the step motors 14, 15, and 16 are disposed in the second region (the other region) R2. And covers all of the step motors 14, 15, 16 disposed in the second region R 2 as viewed from the direction along the support shaft 17 (direction perpendicular to the drawing sheet), and the antenna 13. S not as a structure antimagnetic plates 18 are disposed.

  Here, since the wristwatch 10 of the present embodiment has a calendar function, in addition to the hands for indicating the time of the second hand, the minute hand, and the hour hand, a ring-shaped date wheel (date plate) on which the date is described is also provided. Although it is included as one of the guidelines, it may be one without such a date indicator.

  Further, the magnetic-resistant plate 18 has a shape that covers substantially the entire surface of the second region R2 where the step motors 14, 15, and 16 are disposed, but as shown in FIG. 2, it does not cover the substantially entire surface of the second region R2. The minimum shape that covers the step motors 14, 15, and 16 may be used. By making the shape smaller, weight can be reduced and costs can be reduced.

  A support shaft 17 of a pointer such as a second hand is a shaft that is provided at the center of rotation of the pointer and extends in the thickness direction of the wristwatch 10, and is supported at the approximate center of the dial of the wristwatch 10.

  FIG. 3 is a cross-sectional view of an essential part of the vertical plane including the step motor 14 (the same applies to the step motor 15 and the step motor 16) in the thickness direction of the wristwatch 10 shown in FIG.

  As shown in FIG. 3, each of the stepping motors 14, 15, 16 is provided with a magnetic-resistant plate 18 (a dial plate) disposed on a dial plate 19 side and a back cover (not shown) side in the thickness direction of the wristwatch 10. Are provided so as to be sandwiched between the anti-magnetic plate 18a on the side and the anti-magnetic plate 18b on the back cover side, but only provided with the anti-magnetic plate 18a on the dial plate 19 side or the anti-magnetic plate 18b on the back cover side. There may be.

  In FIG. 3, reference numeral 30 denotes a train wheel mechanism that connects the second and minute hands and the first step motor 14 (the connecting portion is omitted in the cross section of the figure), and reference numeral 35 denotes the fifth wheel, Reference numeral 21 is a wheel train receiver, reference numeral 23 is a circuit block for controlling the driving of the step motors 14, 15, and 16, reference numeral 22 is a main plate, reference numeral 24 is a date wheel, reference numeral 25 is a date wheel presser, and reference numeral 26 is a solar cell. Show.

  According to the wristwatch 10 of the present embodiment configured as described above, each of the stepping motors 14, 15, 16 is covered with the antimagnetic plate 18 when viewed from the direction along the support shaft 17 of the pointer. It is possible to prevent or suppress the influence of magnetism.

  On the other hand, the first region R1 in which the antenna 13 is disposed is a magnetic resistance among the two regions R1 and R2 divided by the virtual vertical plane P including the approximate center of the dial 19 of the wristwatch 10 (support shaft 17 of the pointer). Since it is an area on the side different from the step motors 14, 15, 16 covered by the plate 18, it is arranged far away from the magnetic-resistant plate 18 that absorbs standard time radio waves, and the reception sensitivity of the antenna 13 is lowered. There is no.

  Therefore, the wristwatch 10 prevents or suppresses the influence of external magnetism on the built-in step motors 14, 15, and 16 while preventing the reception sensitivity of the built-in antenna 13 from decreasing. be able to.

  Each step motor 14, 15, 16 is covered from both sides in the thickness direction of the wristwatch 10 by the anti-magnetic plate 18a on the dial 19 side and the anti-magnetic plate 18b on the back cover side. It is possible to further prevent or suppress the influence of external magnetism on the stepping motors 14, 15, 16 than those covered only with the anti-magnetic plates 18 a or 18 b.

  In addition, both the magnetic-resistant boards 18a and 18b may mutually differ in the magnetic-resistance performance. When both the anti-magnetic plates 18a and 18b have already exceeded the desired anti-magnetic performance as a whole, the anti-magnetic performance of one anti-magnetic plate 18a (or 18b) is reduced with respect to the other anti-magnetic plate 18b (or 18a). Even so, as long as the desired anti-magnetic performance can be ensured as a whole of the anti-magnetic plates 18a and 18b, by making one of the anti-magnetic performance lower than that of the other, it is possible to prevent excessive quality and manufacture by reducing the anti-magnetic performance Costs and man-hours can be reduced.

  As a specific configuration for making the magnetic resistance performances of the two magnetic resistance plates 18a and 18b different from each other, the thicknesses of the magnetic resistance plates 18a and 18b are different from each other, or only one of the magnetic resistance plates 18a or 18b is subjected to heat treatment. Thus, a configuration in which no heat treatment is applied to the other anti-magnetic plate 18b or 18a can be applied.

  By making the thickness of one of the anti-magnetic plates 18a or 18b thinner than that of the other anti-magnetic plate 18b or 18a, the thickness of the entire wristwatch 10 can be reduced and the cost can be reduced. You can also.

  From a practical point of view, it is preferable that the thickness of the anti-magnetic plate 18a on the dial 19 side is smaller than the thickness of the anti-magnetic plate 18b on the back cover side. This is because the magnetic back plate 18b on the back cover side also has a function of holding down the train wheel mechanism 30 and the circuit block 23 of the timepiece movement, and therefore is required to be stronger than the magnetic plate 18a on the dial 19 side.

  Further, since the heat treatment is performed only on one of the magnetic-resistant plates 18b or 18a and the heat treatment is not performed on the other magnetic-resistant plate 18a or 18b, the man-hours and costs required for the heat treatment can be reduced.

  The wristwatch 10 of the present embodiment includes the date dial 24, but as shown in FIG. 3, the antimagnetic plate 18 a on the dial 19 side is closer to the back cover than the date dial 24 in the thickness direction of the wristwatch 10. In other words, the date dial 24 is disposed closer to the dial 19 than the magnetic-resistant plate 18a on the dial 19 side.

  Unlike the other time display hands (second hand, minute hand, hour hand), the date indicator 24 needs to be disposed close to the back surface of the dial 19 and is magnetically resistant between the dial 19 and the date indicator 24. When the plate 18a is arranged, it becomes difficult to fix the magnetic resistant plate 18a between the dial plate 19 and the date wheel 24 by screwing or the like to the timepiece movement, and the date window (date display window) in the dial plate 19 is also provided. The shape of the magnetic-resistant plate 18a must be changed so that the magnetic-resistant plate 18a between the dial 19 and the date dial 24 is not exposed from the date window.

  On the other hand, according to the wristwatch 10 of the present embodiment in which the antimagnetic plate 18a on the dial 19 side is arranged on the back cover side of the date dial 24 in the thickness direction of the wristwatch 10, the antimagnetic plate 18a is provided. Even if the position of the date window on the dial 19 changes, the magnetic-resistant plate 18a is hidden behind the date wheel 24 at the position of the date window, even if it is not difficult to fix to the watch movement. The magnetic-resistant plate 18a is not exposed from the window.

  In addition, even if the position of the date window changes due to a design change or the like, it is not necessary to remake the magnetic-resistant plate 18a, so that it is possible to deal with a wide variety of designs.

  Furthermore, as shown in FIG. 1, the wristwatch 10 of the present embodiment is arranged so that its substantially central portion is disposed on a virtual axis Q that is orthogonal to the direction in which the wristwatch band 12 extends and passes through the support shaft 17. An antenna 13 is provided.

  In the extending direction of the watch band 12, a band support portion 11 a for supporting the watch band 12 protrudes from the watch case 11, and when the watch band 12 is made of metal, the band support portion 11 a This causes a decrease in reception sensitivity.

  However, like the wristwatch 10 of the present embodiment, the antenna 13 is arranged so that the substantially central portion thereof is disposed on the virtual axis Q that is orthogonal to the direction in which the wristband 12 extends and passes through the support shaft 17 of the pointer. If it is provided, the antenna 13 is disposed at a position away from the band support portion 11a and the metal wristwatch band 12, so that a decrease in reception sensitivity of the antenna 13 can be suppressed.

  In the wristwatch 10 of the present embodiment, the wristwatch band 12 extends along a line connecting the 12:00 (M12) and 6 o'clock (M6) on the dial 19, so that the antenna 13 has a substantially center portion on the dial. It is arranged so that it is positioned at the upper 9 o'clock (M9) (or 3 o'clock (M3)) to suppress a decrease in the reception sensitivity of the antenna 13.

  Further, as shown in FIG. 4, the antenna 13 of the wristwatch 10 of the present embodiment is formed such that its magnetic core extends over an angle range θ of about 130 degrees around the support shaft 17 of the pointer. Thus, the shape extending in the wide angle range improves the receiving sensitivity of the antenna 13, the arrangement in which the substantially central portion of the antenna 13 is at the 9 o'clock (M9) position on the dial, and all steps. A configuration in which the motors 14, 15, and 16 are arranged in the second region R2 can be easily realized.

  As shown in FIG. 5, in the wristwatch 10 of the present embodiment, when the switch 28 protruding outside the watch case 11 is pressed, the switch 28 is returned to the position before the pressing by the restoring force of the elastic deformation. A metal switch return member 29 having a switch return piece 29a is provided. A part of the switch return member 29 includes a button-type battery 27 which is a power source of the step motor 16 and the like of the wristwatch 10. A battery-side pressure piece 29b that presses the side portion of the button-type battery 27 by elastic restoring force is formed while abutting on the portion.

As described above, the switch return member 29, which is a single member, has two functional parts (the switch return piece 29a and the battery side pressure piece 29b), thereby reducing the number of parts and the cost while arranging the parts efficiently. Can be improved.
(Modification)
In the wristwatch 10 of the above-described embodiment, as shown in the cross-sectional view of the main part in FIG. 6, at least one of the step motors 14, 15, 16 (for example, the step motor 14 for driving the second hand) and the step motor 14 is formed at a predetermined position of the LED 51, the phototransistor 52, and the fifth wheel & pinion 35 for detecting the moving position of the second hand by detecting the displacement position of the wheel train mechanism that couples the pointer (for example, the second hand) driven by the motor 14. The step motor 14 so as to correct the hand movement position of the second hand according to the hand position of the second hand detected by the hand position detecting means and the hand position of the second hand detected by the hand position detecting means. It is also possible to adopt a configuration further provided with a pointer position correcting means composed of circuit blocks 23a and 23b to be controlled.

  Here, in FIG. 6, reference numeral 40 is a hour wheel to which an hour hand is attached, reference numeral 32 is a second wheel to which a minute hand is attached, reference numeral 34 is a fourth wheel to which a second hand is attached, and reference numeral 33 is a second wheel. It is a third wheel that meshes with the wheel 32 and the fourth wheel 34.

  Reference numeral 38 has the same shape as the fourth wheel 34 and is disposed outside the hour wheel 40, and meshes with the fifth wheel 35 to rotate at the same angular velocity as the fourth wheel 34. This is a detection-only car that monitors the movement of the car 34.

  The second wheel 34 is fitted with a second hand and rotates once on the dial 19 in 60 seconds. Therefore, the detection wheel 38 also rotates once in 60 seconds. An opening 38a formed in the detection wheel 38 is It is located on the straight line connecting the LED 51 and the phototransistor 52 shown in the figure only once in 60 seconds.

  Further, the fifth wheel 35 meshes with the fourth wheel 34 and rotates, for example, four times in 60 seconds. The opening 35a formed in the fifth wheel 35 has an LED 51 and a phototransistor 52 shown in the figure four times in 60 seconds. Is located on a straight line connecting

  As a result, the phototransistor 52 has the LED 51 only when the opening 38a formed in the detection wheel 38 and the opening 35a formed in the fifth wheel 35 are simultaneously located on a straight line connecting the LED 51 and the phototransistor 52. LED light L emitted from is received.

  Therefore, the phototransistor 52 matches the timing at which the LED light L is received with the timing at which the second hand indicates 12:00 (M12) of the dial 19, so that the phototransistor 52 receives the LED light L, It is possible to detect a specific hand movement position of the second hand, that is, a timing at which the second hand indicates 12:00 (M12) of the dial 19.

  Then, the circuit blocks 23a and 23b calculate the amount of deviation between the accurate time seconds included in the standard time radio wave received by the antenna 13 and the timing at which the phototransistor 52 receives the LED light L, and this calculation is performed. By driving and controlling the first step motor 14 so as to eliminate the deviation, the second hand can be maintained at an accurate time (second).

  According to the wristwatch 10 of the modified example configured as described above, each of the step motors 14, 15, and 16 is covered with the antimagnetic plate 18 when viewed from the direction along the support shaft 17 of the pointer, and therefore, the external magnetic Can be prevented or suppressed.

  On the other hand, the first region R1 in which the antenna 13 is disposed is a magnetic resistance among the two regions R1 and R2 divided by the virtual vertical plane P including the approximate center of the dial 19 of the wristwatch 10 (support shaft 17 of the pointer). Since it is an area on the side different from the step motors 14, 15, 16 covered by the plate 18, it is arranged far away from the magnetic-resistant plate 18 that absorbs standard time radio waves, and the reception sensitivity of the antenna 13 is lowered. There is no.

  Further, the pointer position detection means detects the specific position of the second hand movement driven by the step motor 14, and the pointer position correction means corrects the second hand movement position according to the movement position detected by the pointer position detection means. Therefore, even if there is an external factor other than external magnetism (for example, input of a physical impact), a highly accurate hand movement operation and a reliable correction operation can be ensured.

  In particular, the second hand in the pointer-type wristwatch 10 has the fastest movement among all the hands. Therefore, even if there is a slight shift in time, the hand movement position (angle) is another hand such as a minute hand or hour hand. It is easy to be visually recognized as a large shift compared to.

  That is, it is mainly the second hand that confirms the presence or absence of a moving position of the hand by looking at the instruction of the second hand when listening to the hourly time signal sent by broadcasting or the like.

  In addition, since the second hand has a smaller holding force with respect to the support shaft 17 than that of the other hands, it is relatively easy to cause a displacement of the hand movement position.

  Therefore, the hand position detection means detects the displacement position of the train wheel mechanism 30 to which the second hand is connected, and the hand position correction means corrects the hand movement position of the second hand, so that the hand movement position deviation of the second hand is visually recognized. Can be reduced.

  Further, among all the stepping motors 14, 15, and 16, only the second wheel train mechanism needs to be provided with the pointer position detecting means. Compared to the configuration provided with the detection means, the number of components can be reduced and the manufacturing cost associated therewith can be reduced.

  In this case, instead of individually providing the pointer position detecting means for each wheel train mechanism corresponding to each of the pointers, all the pointers are provided as shown in FIG. 7 from the viewpoint of reducing the number of components and manufacturing costs. The portions arranged coaxially, that is, the portions where the second hand 34 of the second hand, the second wheel 32 of the minute hand, the hour wheel 40 and the fifth wheel 35 of the hour hand are arranged coaxially, and each opening formed in each of them is formed. A configuration including a single pointer position detection means (LED 51 and phototransistor 52) is also possible so as to detect that 34a, 32a, 40a, and 35a are aligned on a straight line. When the pointer position detecting means is disposed in the portion where the second wheel 32, the hour wheel 40 and the fifth wheel 35 are arranged coaxially, the pointer position detecting means is the fourth position when viewed from the direction along the support shaft 17. Car 34, second Car 32, will be disposed at a position overlapping the hour wheel 40 and the fifth wheel 35, thereby causing an increase in the thickness H of the wrist watch.

  However, in the wristwatch 10 of this modification, for the hour hand and the date indicator 24, the second step motor 15 and the third step motor 16 for driving them are arranged in the second region R2 on the side different from the antenna 13. Moreover, since the step motors 15 and 16 are covered with the magnetic-resistant plate 18, high-precision hand movement operation and reliable correction can be performed without providing a pointer position detecting means for these hour hand and date indicator 24. Operation can be ensured.

  Therefore, it is only necessary to provide a pointer position detecting means only for the second hand that is likely to cause a displacement of the hand movement position compared to other hands, and the pointer position detecting means includes the fourth wheel 34, the second wheel 32, the hour wheel 40, and It is not necessary to arrange at the position overlapping the fifth wheel & pinion 35, and it is possible to prevent the thickness H of the wristwatch from increasing.

  In this modification, the second hand is detected by detecting the displacement position of the detection wheel 38, but the second hand is detected by detecting the displacement position of the wheel train mechanism 30 other than the detection wheel 38. The hand movement position may be detected.

  Further, in this modification, the LED light L transmitted through both the openings 38a, 35a of the detection wheel 38 and the fifth wheel 35 is detected by the phototransistor 52, but instead of forming the opening 38a in the detection wheel 38. Is provided with a reflection plate such as a mirror, and the phototransistor 52 is provided on the same side as the LED 51, and the phototransistor 52 detects the light L transmitted through the opening 35 a of the fifth wheel 35 and reflected by the reflection plate of the detection wheel 38. It is also possible to adopt a configuration to

  In addition to the optical configuration of the LED 51, the phototransistor 52, and the openings 38a and 35a described above, a magnetic configuration or an electrical configuration may be applied as the pointer position detection means.

  The solar cell 26 shown in FIGS. 3 and 6 is fixed by a solar cell support frame 60 as shown in FIG. 8 when viewed from the front side of the dial 19. As shown in FIG. 8, the date wheel 24 is formed in an annular shape.

  As shown in FIG. 9, the wristwatch 10 of the first embodiment and the modified example has an inner peripheral edge of a second presser spring 70 formed by a thin plate elastic member having a substantially frustoconical circumferential surface shape at the shaft portion of the center wheel & pinion 32. On the other hand, a concave portion 22a that is recessed by a depth ΔH is formed on the surface of the main plate 22 that faces the collar surface of the center wheel 32.

  The diameter of the recess 22a is formed to be larger than the outer diameter when the second pressing spring 70 is compressed into a flat shape. The depth ΔH of the recess 22a is set slightly deeper than the thickness when the second pressing spring 70 is compressed into a flat shape.

  The second presser spring 70 applies a constant load to the second wheel 32 and the fourth wheel 34 in order to prevent the minute hand fitted to the second wheel 32 and the second hand fitted to the fourth wheel 34 from fluctuating. However, since the recess 22a is not formed in the base plate 22 conventionally, when the minute hand is pulled out from the second wheel 32 or when the second hand is pulled out from the fourth wheel 34, only the second wheel 32 or the fourth wheel 34 and the second wheel 32 are strongly pulled in the direction of the arrow in FIG. 9 (downward in the drawing), whereby the second holding spring 70 is interposed between the flange surface of the second wheel 32 and the surface of the main plate 22. It was pinched and crushed into a flat plate shape. As a result, the second holding spring 70 sag and lost its elastic recovery force, so that the load to be applied to the second wheel 32 and the fourth wheel 34 could not be applied.

  However, in the present embodiment, the second wheel 32 is pulled strongly in the direction of the arrow so that the second holding spring 70 is sandwiched between the flange surface of the second wheel 32 and the surface of the main plate 22. Since the second holding spring 70 enters the recess 22a having a depth ΔH deeper than the plate thickness of the second holding spring 70, the second holding spring 70 is not crushed until it becomes flat.

Therefore, the second presser spring 70 does not sag, leaving a surplus elastic recovery force, and a load can be applied to the second wheel 32 and the fourth wheel 34.
(Example 2)
FIG. 10 is a diagram showing an internal configuration of the pointer-type radio wave correction wristwatch 10 according to the embodiment of the present invention.

  The wristwatch 10 shown in the figure has an antenna 13 for receiving a standard time radio wave, a first step motor 14 for driving the second and minute hands, a second step motor 15 for driving the hour hand, A third step motor 16 that is driven, and two regions divided by a virtual vertical plane (a plane perpendicular to the plane of the drawing) P including the support shaft 17 of these hands (second hand, minute hand, hour hand, date wheel) Among R1 and R2, the antenna 13 and the first step motor 14 are disposed in the first region R1, the second step motor 15 and the third step motor 16 are disposed in the second region R2, and along the support shaft 17. Viewed from the direction (direction perpendicular to the drawing sheet), the step motors 15 and 16 disposed in the second region R2 are covered, and the antenna 13 and the first step motor 14 are not covered. Is configured to urchin antimagnetic plate 18 is disposed.

  Here, in the first step motor 14 for driving the second hand that is arranged in the first region R1 and is not covered with the magnetic-resistant plate 18, a gear train mechanism that is driven by the step motor 14 as in the above-described modification. By detecting the displacement position of the second hand, the pointer position detecting means comprising the LED 51, the phototransistor 52, etc., which detects the position of the second hand, and the movement of the second hand detected by the pointer position detecting means (the LED 51, the phototransistor 52, etc.) There is provided pointer position correcting means for controlling the first step motor 14 so as to correct the hand movement position of the second hand according to the position.

  According to the wristwatch 10 of the embodiment configured as described above, the second step motor 15 and the third step motor 16 are covered with the antimagnetic plate 18 when viewed from the direction along the support shaft 17 of the pointer. Therefore, it is possible to prevent or suppress the influence of external magnetism.

  On the other hand, since the first step motor 14 is not covered with the magnetic-resistant plate 18 and is easily affected by external magnetism, the hand position detecting means is operated by the second hand driven by the first step motor 14. Since the hand position correcting means corrects the hand position according to the hand position of the second hand detected by the hand position detecting means, the first step motor 14 is also reliable and highly accurate. Corrective action can be ensured.

  Further, the first region R1 where the antenna 13 is arranged is one of the two regions R1 and R2 divided by a virtual vertical plane P including the approximate center of the dial 19 of the wristwatch 10 (support shaft 17 of the pointer). Since it is a region on the side different from the step motors 15 and 16 covered with the magnetic shield 18, it is arranged far away from the magnetic shield 18 that also absorbs standard time radio waves, and the reception sensitivity of the antenna 13 is lowered. There is no.

  Therefore, the wristwatch 10 prevents or suppresses the influence of external magnetism on the built-in step motors 14, 15, and 16 while preventing the reception sensitivity of the built-in antenna 13 from decreasing. be able to.

  Furthermore, since it is not necessary to cover the 1st step motor 14, the magnetic-resistant board 18 can apply a smaller shape, and can aim at the cost reduction accompanying size reduction of the magnetic-resistant board 18. FIG.

  Further, in the wristwatch 10 of the present embodiment, the hour hand and the date indicator are covered with the magnetic resistant plate 18 for the second step motor 15 and the third step motor 16 that drive them, so Thus, it is possible to ensure a highly accurate hand movement operation and a reliable correction operation without providing a pointer position detecting means or the like.

  Therefore, as shown in FIG. 7, it is not necessary to dispose the pointer position detecting means or the like at a position overlapping the fourth wheel 34, the second wheel 32, the hour wheel 40, and the fifth wheel 35, and the thickness of the wristwatch 10 It is possible to prevent H from increasing.

It is a figure which shows the internal structure of the pointer type | mold radio | wireless correction wristwatch which concerns on one Embodiment (Example 1) of this invention. It is a figure which shows the example which made the magnetic-resistant board of the wristwatch shown in FIG. 1 small. It is sectional drawing which shows the principal part cross section of the wristwatch shown in FIG. It is a figure which emphasizes and shows the antenna in the wristwatch shown in FIGS. It is a figure which expands and shows the switch return member in the wristwatch shown in FIGS. It is sectional drawing which shows the principal part cross section of the modification of embodiment shown in FIG. It is sectional drawing which shows the principal part cross section of the comparative example which provided the pointer position detection means in the hour wheel part of the spindle. It is a figure which shows the arrangement | positioning state of a solar cell and a date wheel. It is principal part sectional drawing which shows the improvement which prevents the settling of a 2nd pressing spring. It is a figure which shows the internal structure of the pointer-type electromagnetic wave correction wristwatch which concerns on other embodiment (Example 2) of this invention.

Explanation of symbols

10 Wristwatch (pointer-type radio-controlled watch)
13 Antenna 14 First step motor 15 Second step motor 16 Third step motor 17 Support shaft 18 of pointer (second hand, minute hand, hour hand, date wheel) Magnetic-resistant plate R1 First region R2 Second region

Claims (12)

In a pointer-type radio wave correction watch equipped with an antenna that receives radio waves and a plurality of step motors that drive the hands,
Among the two regions divided by the virtual vertical plane including the pointer support shaft, the antenna is disposed in one region, and at least one of the plurality of step motors is disposed in the other region. ,
A pointer comprising a magnetic-resistant plate disposed so as to cover at least all of the step motors arranged in the other region and not to cover the antenna when viewed from the direction along the support shaft. Type radio wave correction watch.   2. The pointer-type radio-controlled timepiece according to claim 1, wherein all of the plurality of step motors are arranged in the other region. Pointer position detecting means for detecting a moving position of the pointer by detecting a displacement position of a gear train mechanism that connects at least one of the plurality of step motors and a pointer driven by the at least one step motor; ,
The pointer-type radio wave correction timepiece according to claim 2, further comprising pointer position correction means for correcting a hand movement position of the pointer according to a displacement position detected by the pointer position detection means. At least one of the step motors is disposed in one region where the antenna is disposed,
A pointer position detecting means for detecting a moving position of the pointer by detecting a displacement position of a gear train mechanism that connects the step motor arranged in the one region and the pointer driven by the step motor;
Pointer position correcting means for correcting the hand movement position of the pointer according to the displacement position detected by the pointer position detecting means,
The pointer-type radio wave correction timepiece according to claim 1, wherein the magnetic-resistant plate is arranged so as not to cover a step motor arranged in the one region.   5. The pointer type according to claim 3, wherein the pointer position detecting means detects a moving position of the second hand by detecting a displacement position of a wheel train mechanism to which a second hand is connected. Radio correction clock. The pointer position detection means, when viewed from a direction along the support shaft, the pointer according to any one of claims 3, 4, and 5, characterized in that it is arranged at a position not overlapping the hour wheel Type radio wave correction watch.   At least two of the anti-magnetic plates are arranged so as to cover the step motor from both sides of the dial side and the back cover side in the thickness direction of the pointer-type radio-controlled timepiece, respectively. The pointer-type radio wave correction timepiece according to any one of claims 1 to 6. It has a date plate that displays the date,
8. The pointer-type radio wave correction according to claim 7, wherein the dial plate side of the magnetic plate is disposed closer to the back cover than the date plate in the thickness direction. 9. clock.   9. The pointer-type radio-controlled timepiece according to claim 7, wherein the dial-side magnetic-proof plate and the back-cover-side magnetic-proof plate have different magnetic-resistance performance.   The pointer-type radio-controlled timepiece according to claim 9, wherein the dial-side magnetic-resistant plate and the back-side-side magnetic-resistant plate have different thicknesses.   The pointer-type radio-controlled timepiece according to claim 9, wherein only one of the dial-side magnetic-proof plate and the back-cover-side magnetic-proof plate is heat-treated. While supporting a watch band extending in a predetermined direction,
Orthogonal to the direction of extension of the arm watch band, on the virtual axis passing through the pre-Symbol shaft, claim 1, characterized in that pre-Symbol antenna as the center portion is arranged is disposed 11 The pointer type radio wave correction watch according to any one of the above.

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