TW200405146A - Analog electronic timepiece having train wheel setting lever - Google Patents

Abstract

To provide a small-sized and thin analog electronic timepiece having a mechanism capable of firmly setting a train wheel for rotating a small second hand. An analog electronic timepiece includes a main plate, bridge members time information indicating wheels rotated with a main plate center as rotation center, a small second wheel rotated with a position other than a center of a movement as rotation center, a hand setting stem, a switching apparatus and a dial. The analog electronic timepiece includes a reset lever constituted to be able to rotate by operating the switching apparatus when the hand setting stem is pulled out to a first stage and a train wheel setting lever constituted to linearly move based on rotation of the reset lever. In a state of pulling out the hand setting stem to the first stage, a train wheel setting lever can set rotation of the small second wheel or other wheel provided to rotate the small second wheel.

Description

200405146 (1) 发明. Description of the invention [Technical field to which the invention belongs] The present invention relates to a pointer-type electronic watch having a wheel train positioning lever. In particular, the present invention relates to an analog electronic watch with a center, the center can be configured with a chronograph second hand at the center of the center, and the chronograph second hand can be arranged in addition to the center of the analog electronic watch. A position outside the center where the epicenter includes a wheel train locator. Furthermore, the present invention relates to an analog electronic watch with a center which includes a motor and a wheel train for operating a small second hand, wherein the center includes a wheel train positioning lever. [Prior art] Generally, the core of the analog electronic watch (including the body of the driving part) includes a motherboard that forms the base of the core. In an analog electronic watch with two sides of the main board, the side with the dial is called the "back side", and the side opposite to the side with the dial is called the "surface side" of the center. The wheel train integrated into the "surface side" of the epicenter is called the "surface wheel train", and the wheel train integrated into the "back side" of the epicenter is called the "rear wheel train". The "surface side" of the epicenter It is equipped with battery, circuit block, motor, surface gear train and the like. Generally, the surface gear train includes: fifth wheel / pinion, second wheel / pinion, third wheel / pinion, center wheel / pinion ( Split wheel / pinion) and similar wheels. Generally, the motor is structured by a stepper motor and includes a coil block, a stator, and a rotor. In an analog electronic watch, the gear train is rotated by driving the rotor. The rotor Including rotor magnet and rotor pinion (indicating that the rotor except the rotor magnet is the same as follows). (2) (2) 200405146 The center of the "rear side" is equipped with a rear wheel train and the like. Usually, The rear wheel train includes: positioning wheel, hour wheel, split wheel and similar wheels. Furthermore, the switching device is arranged on the "surface side" or "rear side" of the center. Generally, the switching device includes a positioning lever, a yoke, and a yoke. And the like. Furthermore, the pointer positioning lever, clutch wheel, positioning wheel And the like are provided as a pointer positioning mechanism. The analog electronic watch system architecture makes the wheel train rotate by the rotation of the rotor when the stepping motor is operated. The "hour" of the current time is indicated by the hour hand, and the current time The "minute" is indicated by the minute hand. In addition, the analog chronograph system allows the wheel train to rotate by the rotation of the rotor when the stepper motor is operated. The "second" of the elapsed time is indicated by the chronograph second hand. In addition, the "minute" of the past time is indicated by the chronograph minute hand, and the "hour" of the past time is indicated by the chronograph hand. Furthermore, an analogue chronograph is known in which "the elapsed time is in tenths of a second" "Time measured in units of" is indicated by a tenth of a second hand and / or, time measured by elapsed time in units of a fifth of a second "is measured by a fifth of a hour The second hand indicates. The electronic timepiece disclosed in JP-A-63- 1 495 86 is equipped with a motor and a wheel train for indicating the time in the center part of the movement, and is equipped with a motor and a five-hundredth hour hand The gear train, the motor and the gear train for operating the chronograph second hand, and the motor and the gear train for operating the chronograph minute hand are spaced approximately 90 degrees apart on the outer periphery of the core. According to the electronic timepiece with a chronograph disclosed in JP-A-6, 83, 992, the second hand provided with a rotation center at the center of the center of the watch is an abnormal time and chronograph time by operating an outer operating member. Furthermore, the gear train architecture used to drive the second hand -6-(3) (3) 200405146 operates the sS hour and minute hands and chronograph hour hand. The chronograph disclosed in JP_A-55- 1 60890 provides a chronograph second hand with a center of rotation at the center of the center, a chronograph minute hand with a center of rotation at 9 o'clock, and 1 2 with a center of rotation at the dial. Hour hand in the direction of the clock. Furthermore, the motor and the gear train for operating the chronograph second hand, the motor and the gear train for operating the chronograph minute hand, and the motor and the gear train for operating the chronograph hand are arranged on the outer periphery of the watch yL. The chronograph disclosed in JP-A_5 5-7662 provides a chronograph mechanism for operating an indicator indicating time and a chronograph mechanism for operating a chronograph hand. According to this chronograph, the center of rotation of the chronograph second hand is arranged at the center of the center, and the center of rotation of the second hand for watches is arranged between the center of the center and the outer periphery. The conventional analog electronic watch having a small seconds wheel positioned at a position other than the center of the center of the watch creates a problem in which it is difficult to locate a wheel train positioning lever for operating the wheel train for operating the small second hand on the inner side of the center of the watch. . Furthermore, 'especially, in the example of the conventional analog chronograph, according to a chronograph having a structure in which a chronograph second hand is arranged at the center of the center (hereinafter, referred to as a "central chronograph,") , And a chronograph with a structure in which a chronograph second hand is placed at a position other than the center of the center (hereinafter, referred to as a "side-use chronograph"), the size, shape, and configuration of each center part are structured 'In particular, the main board, bridge members (wheel train bridges or similar bridges), stepping motors, and wheel trains are completely different from each other. Therefore, according to this conventional pointer chronograph, when "the central chronograph" and " A chronograph is used on the side. When constructed, the individual watch faces need to be completely separated from each other.

-7- (4) (4) 200405146 is opened, and each of the cores needs to be manufactured through completely separate steps. Therefore, the gear train positioning lever needs to be designed completely separately, which causes a problem in the respective cores, in which the steps of manufacturing the cores are complicated and the number of steps of manufacturing the cores is increased. SUMMARY OF THE INVENTION An object of the present invention is to provide a small and thin analog electronic watch, which includes a small second hand with a center of rotation other than the center of the center of the watch, and includes a small second hand that can be firmly positioned to rotate the small second hand. Of the wheel system. Another object of the present invention is to provide a small and thin analog electronic watch, which has a mechanism capable of firmly positioning the wheel train for rotating the small second hand in a structure that can be configured with a second hand at the center of the watch. The center can be arranged with a chronograph second hand at a position other than the center of the movement, and a small chronograph in particular has a small second hand at a position other than the center of the movement. The invention is characterized in that: an analog electronic watch includes: a main board, a substrate for constructing the core; a bridging member for supporting the component for constructing the core; a time information indicating wheel, using the center of the main board of the main board as Rotate at the center of rotation to indicate time information; a small second wheel to rotate at a position other than the center of the watch center as the center of rotation; a pointer positioning lever to correct the time information indication; a switching device, Used to switch the position of the pointer positioning lever; a dial to indicate the time information; a reposition lever, when the pointer positioning lever is pulled out from the zero stage to the first stage, the weight -8- (5) (5) 200405146 positioning lever structure to cause rotation by operating the switching device; and a gear train positioning lever 'When the pointer positioning lever is pulled out from the zero stage to the first stage, the gear train positioning lever architecture is based on the rotation of the repositioning lever Instead, it moves linearly, wherein the gear train positioning mechanism causes rotation of the small seconds wheel or other wheels used to rotate the small seconds wheel. According to this structure, the gear train positioning rod system moves linearly, and therefore, the positioning part of the gear train positioning rod is brought into contact with a wheel, and the wheel is positioned by operating in a vertical direction from the wheel. Therefore, when the wheel train positioning lever sets the positioned wheel, there is little concern that the rotation of the wheel train positioning lever will be set by the wheel. According to the pointer type electronic timepiece of the present invention, the gear train positioning lever train is configured so that the components attached to the hands do not overlap, that is, the time information indicating wheel and the small second wheel. According to this structure, since the wheel train positioning lever train is provided with the components with no pointer attached thereto ', the thickness of the electronic watch can be reduced. Furthermore, the analog electronic timepiece according to the present invention may be configured to overlap the small seconds wheel. According to this architecture, the gear train positioning rod train is configured to overlap the small seconds wheel, and therefore, the thickness of the electronic watch can be reduced. According to the pointer electronic watch of the present invention, preferably, the repositioning lever includes: a reposition conductive spring for performing a reset operation, a gear train repositioning lever holding part for holding the gear train positioning lever, and for operating the Operating spring of gear train positioning lever. According to this architecture, the relocation operation and the positioning operation can be implemented with certainty by these two components. Preferably, the analog electronic watch according to the present invention, wherein the main board reference vertical axis passing through the center of the main board and parallel to the central axis of the pointer positioning rod, and the main board reference passing through the center of the main board and perpendicular to the main board referring to the vertical axis are referenced to 9- 6) (6) 200405146 The horizontal axis is defined on the main board; wherein the main board is provided with a first zone, which is arranged on one side of the main board reference vertical axis and on the side of the main board reference horizontal axis close to the pointer positioning rod, the The main board is provided with a second zone, which is arranged on the other side of the main board reference vertical axis and on the side of the main board reference horizontal axis which is close to the pointer positioning rod. The main board is provided with a third zone, which is arranged in the presence of the second zone. On the other side of the main board reference vertical axis of the zone and on the side of the main board reference horizontal axis away from the pointer positioning rod, and the main board is provided with a fourth zone which is arranged on the main board reference vertical where the first zone exists On the other side of the axis and on the side of the main board reference horizontal axis away from the pointer positioning rod; wherein the rotation center of the small second wheel is arranged on the main board reference horizontal axis Above the line, above the boundaries of the first zone and the fourth zone, and between the center of the main board and the main board and the outline; the rotation center of the relocation lever is arranged in the second zone; The part of the wheel train positioning lever and the reposition lever which are in contact with each other are arranged in the first zone; and the positioning part of the wheel train positioning lever is brought into the part system in contact with the wheel to be positioned. Configured in this fourth zone. With this structure, a small and thin pointer electronic watch with a gear train positioning lever can be surely implemented. Further, preferably, the analog electronic watch according to the present invention, wherein the wheel train positioning rod includes two guide windows, the main board includes two guide pins for guiding the wheel train positioning rod, and the wheel train positioning rod. The guide windows are separately structured to be guided by the guide pins of the main board, the wheel train positioning rod system is integrated to the main board so as to cause linear movement relative to the main board, and one of the guide pins is arranged at The first zone and the other are located in the fourth zone. Furthermore, the analog electronic watch of the present invention is characterized in that: the main board -10- (7) (7) 200405146 includes a rotor and a gear train support for constructing a "central chronograph" by using the table core. Part, and the supporting part of the rotor and gear train constructed by using the table core, side with a chronograph, wherein the bridge member includes: constructing the "central record by using the table core" The rotor of the timepiece and the supporting part of the wheel train ', and the rotor and the supporting part of the gear train of the "side-use chronograph" by using the core; the construction is used for the " The center uses a chronograph, the rotor and the gear train are integrated to cause rotation with respect to the support portion of the main board and the support portion of the bridge member; wherein the time information is rotated by using the center of the main board as a rotation center. A time indicating member and another time indicating member that rotates with the position between the center of the main board and the outer shape of the main board as a rotation center; one of the time measurement results is rotated by using it as the center of rotation Timing indicator And another timing indicator member that rotates with the position between the center of the main board and the outline of the main board as the rotation center; the repositioning lever can be rotated by operating the switching device when the pointer positioning lever is zero When the stage is pulled out to the first stage; and when the pointer positioning lever is pulled out from the zero stage to the first stage, a wheel train positioning lever moves linearly based on the rotation of the reposition lever; wherein the wheel train positioning lever architecture The rotation of a positioning wheel is caused to rotate a wheel train for rotating another time indicating member. Preferably, the analog electronic watch according to the present invention, wherein the wheel train positioning lever includes two guide windows, and the main board includes two guides. In order to guide the guide pin of the wheel train positioning lever, the guide window parts of the wheel train positioning lever are separately structured to be guided by the guide pins of the main board, and the wheel train positioning lever is integrated into the main board so that relative to The linear movement of the main board, and one of the guide pins is arranged in 4 ΑΓ 1 ^ 0 -11-(8) (8) 200405146 The first zone of the table and the other is arranged in the fourth zone. [Implementation Way] The following will explain The mode of applying the present invention. (1) First embodiment The following will explain the first embodiment of the analog electronic watch according to the present invention. The first embodiment of the present invention is a center three-pointer type. That is, the analogue chronograph has a structure in which a chronograph second hand is positioned at a position other than the center of the watch center and a second hand is provided to indicate that the time is at the center of the watch center. (1 · 1) Definition of the overall structure of the watch movement and technical terms First, the overall structure of the watch movement of the pointer chronograph according to the present invention will be explained. Referring to Figs. 1 to 3, an analog chronograph according to the present invention is provided with a center 100. The bezel 100 includes a motherboard 102 that frames its substrate. According to an embodiment of the present invention, the outer shape of the main board 102 is substantially circular. Furthermore, the shape of the 'main board 102' may be a quadrangular, polygonal, oval, or similar shape. Preferably, the outer shape of the main board 2 is a circular shape, and the outer shape of a part thereof is cut as shown in FIG. 1. According to the embodiment of the present invention, the motor, the surface gear train (including the motor and the surface gear train for driving the surface gear train), the battery, the circuit block, and the switching device are arranged in the core 100, and the motherboard 102 is used as a reference. On the side opposite to the side with the dial 104, that is, on the surface side of * Centre] 〇2 (main board 1 〇2). The rear wheels are bridged. The 8 series is configured with the motherboard 102 as a reference. -12- (9) (9) 200405146 is placed on the side with the dial 104. The switching device includes a pointer positioning lever 1 1 0 ′ for correcting time information. The clutch wheel 1 3 2, a positioning lever 1 3 4, and a yoke 1 3 can rotate the positioning wheel 1 3 0 by the rotation of the pointer positioning lever 1 1 〇. 6. The crown 100 is formed with an irregular part of the yoke 1 36 to be able to pull the pointer positioning lever 1 10 to the first stage. By the spring force of the spring portion of the yoke 1 3 6, the irregular portion of the yoke 1 3 6 is pushed to the side of the front end portion of the positioning lever 134. With this structure, the position of the positioning lever 134 is determined, and further, the setting weight of the pointer positioning lever 110 is set. According to the analog chronograph, it is assumed that at the stage of attaching the dial 104 to the center 100, the direction from the center 300 of the center 1000 to the 12 o'clock scale of the dial 104 is referred to as the "12 o'clock direction" (Figure The indication in 1 is “1 2H”), the direction from the center of the watch center 1 0 0 to the 3 o'clock scale of the dial is called the “3 o'clock direction” (indicated as “3H” in FIG. 1), The direction of the center 3 00 of the center 100 pointing to the 6 o'clock scale of the dial is called the "6 o'clock direction" (indicated as "6H" in Figure 1), and the center 3 00 of the center 100 points to the dial The direction of the 9 o'clock scale is called the "9 o'clock direction" (indicated in Figure 1, such as, 9 Η ,,) ° The pointer positioning lever Π 0 can be rotated and integrated into the main board 1 〇2, and the pointer positioning lever 1 1 〇 is rotated The axis line is configured to coincide with a straight line pointing from the center of the center of the 00 to the "3 o'clock direction". In FIG. 1, on the main board 102, the rotatable center of the center wheel / pinion 224 passing through the side 3 0 0 (hereinafter referred to as "motherboard center 3 0 0,") and the center axis of the parallel pointer positioning rod 1 10 with reference to the vertical axis 3 02 and through the motherboard The main reference water at the center 3 00 and the vertical main board with reference to the vertical axis 3 02 -13- (10) (10) 200405146 The horizontal axis 304 is defined. In the main board 102, the first area 310 is provided for positioning on the side of the main board reference vertical axis 302 'and on the side of the main board reference horizontal axis 304 near the pointer positioning lever 110. On the main board 1 02, the second zone 3 2 0 is provided for positioning on the other side of the main board reference vertical axis 3 0 2 and on the side of the main board reference horizontal axis 304 close to the pointer positioning lever 1 1 0 on. In the main board 102, the third zone 3 3 0 is provided for positioning on the other side of the main board reference vertical axis 302 where the second zone 3 20 exists, and at the main board reference level away from the pointer positioning lever 1 1 0 On the side of the axis 3 04. In the main board 102, the fourth zone 340 is provided for positioning on the side where the main board reference vertical axis 302 of the first zone exists, and on the side away from the pointer reference lever 1 1 0 of the main board reference horizontal axis 304. on. Although in FIG. 1, the first area 310 and the fourth area 340 are defined on the right side of the motherboard reference vertical axis 302, as shown in a modified example, the first area 310 and the fourth area 340 may be defined to be arranged in the The main board is referenced to the left of the vertical axis 302. In this example, the second zone 3 20 and the third zone 3 3 0 are bounded and arranged on the right side of the motherboard reference vertical axis 302. (1. 2) Architecture of the train wheel department for indicating time Next, the architecture of the train wheel department for indicating time will be explained. The gear train portion for indicating time includes a gear train driving motor for indicating time and a gear train for indicating time. Referring to Figs. 1 to 3, the "surface side of the epicenter 100" is provided with a circuit block, a battery 20, a side surface wheel train section, a chronograph minute / second wheel train section, a 1/10 second wheel train section, Switching device, etc. Main board 102, wheel train bridge (a) 106 and wheel -14- (11) (11) 200405146 series bridge (B) 107 constitute supporting members. The central tube 103 is fixed to the main board 102 with the center of the main board 300 is used as the central shaft. The side sun gear / pinion 224 is rotatably integrated into the center hole of the center tube 103. The side sun gear / pinion 224 includes a side sun gear 224a and a side hollow shaft pinion 224b. The side center wheel 224a can slide and integrate the side hollow shaft pinion 224b with respect to the side hollow shaft pinion 224b. The outer periphery of the cylindrical portion of the side hollow shaft pinion 224b is rotatably integrated into the center tube 103. Center hole. The side center wheel 224a is arranged between the main board 102 and the wheel bridge (A) 106. The side center wheel 224a system is integrally rotated with the side hollow shaft pinion 224b. The side surface wheel train The section includes a side surface gear train driving motor, that is, a side time motor and a side hour indicating gear train. By the rotation of the side time motor, the side uses the hour to indicate that the gear train is rotated. The "hour" of the current time is indicated by the hour hand 230, and the current time "minute" is indicated by the minute hand 23 2 and the current time " "Second" is indicated by the second hand 234. Crystal units 1 1 4 and 1C (Integrated Circuit) 1 1 6 are attached to a circuit block (not shown). The circuit block is through an insulating plate (not shown) by The switch spring 122 is fixed to the main board 102, the wheel train bridge (A) 106, and the wheel train bridge (B) 107. The battery 120 is composed of a silver battery, a lithium battery, or a similar battery to form a power source for the analog chronograph. The power supply of the analog chronograph, the rechargeable auxiliary battery can be used or the rechargeable container can be used. The crystal oscillator in the crystal unit 1 1 4 constitutes the oscillator source of the analog chronograph, and it oscillates at, for example, 3 2 76 8Herz. The negative 128-cell architecture of the battery conducts the negative electrode of battery 120 and the negative -15 of IC116 via the negative pattern of the circuit block. (12) (12) 200405146 input section. In the time indication mode, 1C (Integrated Circuit) ) 1 1 6 series architecture to measure the current time The side time motor includes the side time coil block, the side time stator 2 4 4 and the side time rotor, that is, the time rotor (a) 2 4 6. When the 1C (product When the time motor drive signal output from the body circuit 116 is input to the time coil block 242, the side time stator 244 is magnetized to rotate the time rotor (A) 246. The time rotor (A) 246 is configured to rotate, for example, 180 per second degree. The time rotor (A) 246 includes an upper shaft portion 246a, a lower shaft portion 246b, a pinion portion 246c, and a rotor magnet 246d. The upper shaft portion 246a of the time rotor (A) 246 is rotatably integrated with the upper support portion 10a of the time rotor (A) provided at the gear train bridge (A) 106. The lower shaft portion 246b of the time rotor (A) 2 4 6 is rotatably integrated with the lower support portion 102a of the time rotor (A) provided on the main board 102. Therefore, the time rotor (A) 246 series is rotatably arranged between the wheel bridge (A) 106 and the main board 102. Based on the rotation of the time rotor (A) 246, the side uses the second wheel / pinion 221 system structure, ie, the side of the time fifth wheel / pinion (A) 220 uses the rotation of the time fifth wheel / pinion to Spin. The time fifth wheel / pinion (A) 220 includes an upper shaft portion 220a, a lower shaft portion 220b, a pinion portion 220c, and a wheel portion 220d. The wheel portion 220d of the time fifth wheel / pinion (A) 220 is configured to mesh with the pinion portion 246c of the time rotor (A) 246. The upper shaft portion 220a of the time fifth wheel / pinion (A) 220 is rotated and integrated with the time fifth wheel / pinion (A) upper support portion 106b provided at the wheel bridge (A) 106. The lower shaft part 220b of the time fifth wheel / pinion (A) 220 is rotated to integrate the lower bearing part of the time fifth wheel / pinion (A) -16- (13) (13) 200405146 102b. Therefore, the time fifth wheel / pinion (A) 220 series is rotatably disposed between the wheel train bridge (A) 106 and the main board 102. The second side wheel / pinion 221 includes an upper shaft portion 221a, an abacus bead portion 221b, a pinion portion 221c, and a wheel portion 221d. The wheel portion 221 d system of the second wheel / pinion 221 is used to mesh with the pinion portion 220c of the time fifth wheel / pinion (A) 220. The upper shaft portion 221a of the second side wheel / pinion gear 221 is rotatably integrated with the upper side wheel portion 106c of the second wheel / pinion gear provided at the wheel bridge (A) 106. The abacus bead portion 221b of the second side wheel / pinion 221 is rotatably disposed inside the center hole of the side hollow pinion 224b. The center of rotation of the side second wheel / pinion 22 1 is the main board center 3 00. The side uses the second wheel / pinion 221 system structure to rotate every minute. The second hand 234 is attached to the side second wheel / pinion 221. The second hand 234 constitutes a second indicating member. As a second indicating member, a second hand may be used, a circular dial may be positioned, or other shape indicating members including flowing or geometric shapes may be used. The second side wheel / pinion holding spring 23 1 is used to apply pressure to the second side wheel / pinion 221. Based on the rotation of the second side wheel / pinion 221, the side center wheel / pinion 224 system is rotated via the rotation of the third side wheel / pinion 222. The third side wheel / pinion gear 222 includes an upper shaft portion, a lower shaft portion, a pinion portion 222c, and a wheel portion 222d. The wheel portion 222d of the side third wheel / pinion 222 is configured to mesh with the pinion portion 221c of the second side wheel / pinion 221. The upper shaft of the third wheel / pinion 222 for the side is rotatably integrated to the upper support of the third wheel / pinion (A) at the side of the wheel train bridge (A) 1 06-17- (14) (14 200405146 receiving section 106d (refer to the diagram of the gear train bridge (A) 106 described later). The lower shaft portion of the third wheel / pinion 222 for the side is rotatably integrated with the lower support portion 102d of the third wheel / pinion (A) for the side of the main plate 102 (refer to the drawing of the main plate described later). Therefore, the side third wheel / pinion 222 train is rotatably arranged between the train wheel bridge (A) 1 06 and the main board 102. The side wheel / pinion 224 system is used for one revolution per hour. The minute hand 232 constitutes a minute indicating member. As a minute indicator member, a minute hand may be used, a circular dial may be used, or other shape indicator members including flow or geometry may be used. Based on the rotation of the side center sun gear / pinion 224, the hour wheel 228 system is rotated by the rotation of the minute wheel 226. The minute wheel 226 includes an upper shaft portion 226a, a lower shaft portion 226b, a pinion portion 2 2 6 c, and a wheel portion 2 2 6 d. The wheel portion 226d of the minute wheel 226 is structured to mesh with the pinion portion of the side hollow shaft pinion 224b of the side second wheel / pinion 221. The upper shaft portion 226a of the minute wheel 226 is rotatably integrated with a minute wheel upper support portion 106e provided on the wheel bridge (A) 106. The lower shaft portion 226b of the minute wheel 226 is rotatably integrated with a minute wheel lower support portion 102e provided on the main plate 102. The wheel portion 226d of the minute wheel 226 is rotatably disposed between the wheel bridge (A) 106 and the main plate 102. The pinion portion 226c of the minute wheel 226 is rotatably disposed between the main plate 102 and the rear wheel bridge 108. The hour wheel 228 is a peripheral portion of the central tube 103 that can be rotated and integrated. The hour wheel portion 22 8d of the hour wheel 228 is rotatably disposed between the main plate 102 and the rear wheel bridge 108. The rotation center of the hour wheel 228 is the center of the main board 300. Therefore, the center of rotation of the hour wheel 22 8 and the second wheel / pinion 221 of the side are -18- (15) (15) 200405146. The center of rotation is arranged at the same position as the center of rotation of the side wheel / pinion 224 . Time wheel 2 2 8 series architecture to rotate once every 12 hours. The second hand 234 is attached to the hour wheel 22 8. The second hand 234 constitutes an hour indicating member. As an hour finger, the hour hand can be used, a round dial can be used, or other shapes of indicating members including flowing or geometric shapes can be used. When the pointer positioning lever 110 is rotated to the stage where the pointer positioning lever 110 is pulled out to the first stage, the clutch wheel 132 is rotated and the positioning wheel 130 is configured to be able to rotate by the rotation of the clutch wheel 1 2 . Furthermore, the time can be set by rotating the minute wheel 2 2 6 by the positioning wheel 130. The repositioning lever 140 includes a repositioning conductive spring 140d and a wheel train positioning portion 14f. At the stage where the pointer positioning lever 110 is pulled out to the first stage, the gear train positioning part 1 40f of the repositioning lever i 40 is set to set the timing of the fifth wheel / pinion (a) 2 2 0 rotation. For the pointer positioning lever 丨! 〇The stage of pulling out to the first stage is caused by the repositioning pattern of the conductive spring l40cJ to the circuit block's pointer type chronograph system to cause repositioning. (I 3) The structure of the hour-minute / second-indicating wheel train section will then 'explain that the hour-minute / second-indicating wheel of the analog electronic watch (pointer-type chronograph) according to the present invention is operated by the timekeeping side mode Department structure. The hour-minute / second-indicating train wheel unit includes a motor for driving the hour-minute / second-indicating train wheel and the hour-minute / second-indicating train wheel. Referring to FIG. 1 ', the hour-minute / second-indicating gear train portion includes a motor for driving the hour-minute / second-indicating gear train, that is, the hour-minute / second-motor, and the hour-minute / second finger train. Hour-minute / second-indicating gear train that is rotated by the rotation of the hour-minute / second motor, and the elapsed time measured in the chronograph measurement mode, hour-minute, • 19- 204 (16) (16 200405146 is represented by an hour and minute hand, and "chronograph seconds" of the elapsed time measured in the chronograph mode is represented by an hour and second hand. In the chronograph measurement mode, 1C (integrated circuit); 1 6 series architecture to measure the past time and operate the chronograph minute / second motor. The hour / minute / second motor includes a hour / minute / second coil block 262, a hour / minute / second stator 264, and a hour / minute / second rotor 266. The size and shape of the hour / minute / second coil block 262 can be made the same as the size and shape of the time coil block 242. The size and shape of the hour / minute / second stator 264 can be made the same as the size and shape of the side time stator 244. When the hour-minute / second motor drive signal output by 1C (Integrated Circuit) 1 16 is input to the hour-minute / second coil block 2 62, the hour-minute / second stator 2 64 is magnetized to rotate the hour-minute / second. Second rotor 266. The hour / minute / second rotor 266 system rotates, for example, 180 degrees per second. The hour / minute / second rotor 266 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a rotor magnet. The upper shaft part of the minute wheel 226 is rotatably integrated with the chronograph minute / second rotor upper support part 107f provided in the wheel train bridge (B) 107 (refer to the diagram of the wheel train bridge (B) 107 described later). . The lower shaft portion of the hour / minute / second rotor 266 is rotatably integrated with the hour / minute / second rotor lower support portion 102f provided on the main plate 102 (refer to the drawing of the main plate described later). Therefore, the chronograph minute / second rotor 266 is rotatably disposed between the wheel bridge (B) 107 and the main plate 102. Based on the rotation of the chronograph minute / second rotor 266, the chronograph minute / second fifth wheel / pinion 250 0 system is rotated. Based on the rotation of the fifth wheel / pinion 250 of the hour / minute / second, the chronograph intermediate wheel (A) 251 and the scoring intermediate wheel (A) 2 5 2 system rotate. Hours, minutes / seconds, fifth wheel / pinion 2.5 packs -20- (17) (17) 200405146 Including the upper shaft part, the lower shaft part, the pinion part and the wheel part. The upper shaft structure of the fifth hour / second fifth wheel / pinion 2 50 is configured to mesh with the small gear portion of the second minute rotor 2 6 6. Hours, minutes / seconds, fifth wheel / pinion 2 50's upper shaft is rotatably integrated into the hour, minute / second, fifth wheel / pinion upper support portion l0, which is located on the wheel bridge (B) 1 07. 7g (refer to the diagram of the train wheel bridge (B) 107 described later). Hours, minutes / seconds, fifth wheel / pinion 2 50's lower shaft is rotatably integrated into the hour, minute / second, fifth wheel / pinion lower support portion 102g provided on the main board 102 (refer to the main board described later) Figure). Therefore, the hour-minute / second fifth-wheel-to-pinion 250 series is rotatably arranged between the train bridge (B) 107 and the main board 102. Based on the rotation of the chronograph intermediate wheel (A) 25 1, the chronograph wheel 254 system is configured to rotate via the rotation of the chronograph intermediate wheel (B) 253. The chronograph intermediate wheel (A) 25 1 has the same size and shape as the chronograph intermediate wheel (B) 2 5 3. The chronograph intermediate wheel (A) 251 includes: an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel mechanism of the chronograph intermediate wheel (A) 25 1 meshes with the small teeth of the fifth wheel / pinion 250 of the hour / minute / second. The upper shaft of the chronograph intermediate wheel (A) 251 is rotatably integrated with the upper support portion 108h of the chronograph intermediate wheel (A) provided at the rear wheel bridge 108 (refer to the rear wheel bridge described later) Figure). The lower shaft portion of the chronograph intermediate wheel (A) 2 51 is rotatably integrated with the bottom support portion 102h of the chronograph intermediate wheel (A) provided on the main plate 102 (refer to the drawing of the main plate described later). Therefore, the chronograph intermediate wheel (A) 2 5 1 series is rotatably arranged between the rear wheel bridge 108 and the main board 102. Counter intermediate wheel (B) 2 5 3 includes: upper shaft part, lower shaft part and wheel -21-(18) (18) 200405146. The wheel of the chronograph intermediate wheel (B) 2 5 3 meshes with the wheel of the chronograph intermediate wheel (A) 2 5 1. The upper shaft of the chronograph intermediate wheel (B) 2 5 3 can be rotatably integrated to the rear wheel bridge. 〇8 The chronograph intermediate wheel (B) upper support 1 0 8 j (refer to the later description) Diagram of gear train bridging). The lower shaft of the chronograph intermediate wheel (B) 2 5 3 is rotatably integrated into the bottom support portion 1 02 of the chronograph intermediate wheel (B) provided on the main board 102 (refer to the diagram of the main board described later). . Therefore, the chronograph intermediate wheel (B) 2 5 3 series is rotatably arranged between the rear wheel train bridge 108 and the main board 102. The seconds wheel 254 includes an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel system of the chronograph wheel 254 engages with the wheel of the chronograph intermediate wheel (B) 253. The upper axle portion of the chronograph wheel 254 is rotatably integrated with the chronograph wheel upper support portion 108k provided at the rear wheel bridge 108 (refer to the diagram of the rear wheel bridge described later). The lower shaft of the seconds wheel 2 5 4 can be rotated and integrated into the main board! 02 chronograph lower support part 02k (refer to the diagram of the main board described later). Therefore, the second wheel 2 5 4 series is rotatably arranged between the rear wheel bridge 108 and the main board 102. A second chronograph hand 25 5 (refer to a drawing described later) is attached to the chronograph wheel 254. The second chronograph hand 25 5 frames a second chronograph indicator. In the chronograph measurement mode, the seconds hand 2 5 5 is operated to indicate the "second" of the elapsed time. Referring to FIG. 1, the rotation center of the second wheel 2 5 4 is arranged above the reference horizontal axis 304 of the main board and between the main board center 3 00 and the outline part 306 of the main board 102. The main board 102 is arranged at 6 of the bezel 100. O'clock. The distance between the center of rotation of the chronograph wheel 254 and the center of the main board 300 is about 1/2 of the radius of the largest outer shape of the main board 102. -22- (19) (19) 200405146 Based on the rotation of the scoring intermediate wheel (A) 252, the scoring wheel 2 5 8 system is structured to rotate via the rotation of the scoring intermediate wheel (B) 2 5 7. The scoring intermediate wheel (A) 25 2 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a wheel portion. The scoring intermediate wheel (A) 2 5 2 has a wheel structure to mesh with the small teeth of the fifth wheel / pinion 2 50 0 of the hour / minute. The upper shaft of the scorer intermediate wheel (A) 252 is rotatably integrated with the upper support portion 108m of the scorer intermediate wheel (A) provided at the rear wheel bridge 108 (refer to the diagram of the rear wheel bridge described later) ). The lower shaft portion of the scoring intermediate wheel (A) 252 is rotatably integrated into the bottom support portion 102m of the scoring intermediate wheel (A) provided on the main plate 102 (refer to the drawing of the main plate described later). Therefore, the scorer intermediate wheel (A) 252 series is rotatably disposed between the rear wheel train bridge 108 and the main board 102. The scoring intermediate wheel (B) 2 5 7 includes: an upper shaft portion, a lower shaft portion, a pinion gear portion, and a wheel portion. The scoring intermediate wheel (B) 25 7 system is configured to mesh with the pinion portion of the scoring intermediate wheel (A) 2 5 2. The upper shaft of the scoring intermediate wheel (B) 25 7 is rotatably integrated with the upper supporting part 108η of the scoring intermediate wheel (B) provided at the rear wheel bridge 108 (refer to the diagram of the rear wheel bridge described later). . The lower shaft portion of the scoring intermediate wheel (B) 25 7 is rotatably integrated with the bottom supporting portion 102n of the scoring intermediate wheel (B) provided on the main board 102 (refer to the drawing of the main board described later). Therefore, the scoring middle wheel (B) 2 5 7 series is rotatably arranged between the rear wheel train bridge 108 and the main board 102. The scoring wheel 258 includes an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel structure of the scoring wheel 2 5 8 is engaged with the wheel of the scoring intermediate wheel (B) 2 5 7. The scoring wheel 25 8 is rotatably integrated with a scoring wheel upper support portion 108ρ provided on the rear wheel bridge 108 (refer to the -23 · (20) (20) 200405146 picture of the rear wheel bridge described later). The lower shaft portion of the scoring wheel 25 8 is rotatably integrated with the scoring wheel lower support portion 10 2p provided on the main board i02 (refer to the diagram of the main board described later). Therefore, the scoring wheel 25 8 series is rotatably arranged between the rear wheel train bridge 108 and the main board 102. A minute hand 2 5 9 (refer to the complete figure described later) is attached to the scoring wheel 25 8. Minute Hour Hand 2 5 9 Structure a minute hour indicator. In the chronograph measurement mode, the minute hand 25 9 is operated to indicate the "minute" of the elapsed time. Referring to FIG. 1, the rotation center of the scoring wheel 2 5 8 is disposed above the reference vertical axis 3 2 of the main board and between the main board center 3 0 0 and the outer part 3 09 of the main board 1 02 at the center 100. At 9 o'clock. " The distance between the center of rotation of the scoring wheel 258 and the center of the main board 300 is about 1/2 of the radius of the largest external shape of the main board 102. (1, · 4) The architecture of the 1/10 second instruction wheel train section will then explain the 1/1/10 second instruction that operates in the chronograph measurement mode in the pointer electronic watch (pointer chronograph) according to the present invention. The architecture of the train department. The 1/10 seconds gear train includes a motor for driving 丨 /; the 10 seconds gear train and the W 10 seconds gear train. Referring to Figures 1 to 3, the 1/10 seconds motor includes: 1/1/10 seconds coil block 2 8 2, 1/10 seconds second stator 2 8 4 and 1/10 seconds second rotor 2 8 6. 1/10 seconds The size and shape of the coil block 2 82 can be made the same as the size and shape of the time coil block 242. The size and shape of the 1/10 second stator 284 can be made the same as the size and shape of the side time stator 244. When the 1/10 second motor drive signal output by 1C (integrated circuit) 1 16 is input to the 1/10 second coil block 2 8 2, the 1 2/10 second stator 2 8 4 is magnetically -24- ( 21) (21) 200405146 Turns the rotor 2 8 6 for 1/10 seconds. The rotor 2 8 6 is configured to rotate, for example, '180 degrees every 1/10 seconds. The 1/10 second rotor 2 8 6 includes an upper shaft portion 286a, a lower shaft portion 286b, a pinion portion 28 6c, and a rotor magnet 2 8 6d. The upper shaft part 2 8 6a of the 1/10 second rotor 2 8 6 is rotated and integrated with the 1/10 seconds rotor upper support part 〇〇 6 r provided on the wheel train bridge (A) 106. The lower shaft portion 286b of the 1 / 丨 0 second rotor 286 is rotatably integrated with the 1/10 second rotor lower support portion 10 2 r provided on the main board 102. Therefore, the 1/10 second rotor 2 8 6 series is rotatably arranged between the wheel train bridge (A) 106 and the main board 102. The time rotor (A) 2 4 6, the hour-minute / second rotor 26 6 and the 1/10 second rotor 286 are the same components. However, although the time rotor (a) 246 and the chronograph minute / second rotor 2 6 6 are integrated by arranging the pinion portion on the upper side (the integration makes the pinion portion close to the gear train bridge (A) 1 0 6), : I / 10 second rotor 2 8 6 is integrated by arranging the pinion portion on the lower side (the integration makes the pinion portion close to the main board 102). Based on the rotation of the rotor 2 8 6 in 1/10 seconds, the fifth wheel / pinion 270 series structure in 1/10 seconds to rotate. The 1 / 10th second wheel / pinion 270 includes an upper shaft portion 270a, a lower shaft portion 270b, an upper pinion portion 270c, a wheel portion 270d, and a lower pinion portion 270f. The wheel portion 270d of the 1/10 second fifth wheel / pinion 270 is configured to mesh with the pinion portion 286c of the 1/10 second rotor 286. The upper shaft portion 270a of the fifth wheel / pinion 270 in 1/10 second is rotatably integrated with the fifth wheel / pinion upper support portion 106s provided in the wheel bridge (A) 106. The lower shaft portion 270b of the fifth wheel / pinion 270 in 1/10 seconds is integrated by rotation and the lower bearing portion 102s of the fifth wheel / pinion in 1/10 seconds. Therefore, the 5th wheel / pinion 270 series can be rotatably arranged between the wheel bridge (A) 106 and the main board -25- (22) 200405146 1 0 2 in 1Π0 seconds. Based on the rotation of the fifth wheel / pinion 270 in 1/10 second, the 1/1 () counter wheel (B) 272 is rotated through the 1/1 10-second counter wheel (A) 271. The size and structure of the 1/10 stopwatch intermediate wheel (A) 2 7 1 is the same as the size of the 1/10 stopwatch intermediate wheel (B) 272. The 1/10 chronograph intermediate wheel (A) 271 includes an upper shaft portion 271a, a portion 2 7 1 b, and a wheel portion 2 7 1 d. The 1/1/10 second wheel intermediate wheel (a) 2 7 1 is a 271d system to mesh with the lower wheel part 2 7 0 f of the fifth wheel / pinion gear 270 for 1/10 second. The upper 271a series of the 1/10 chronograph intermediate wheel (A) 2 71 can be rotatably integrated to the 1 / 10th middle counter (A) support part 108t provided on the rear wheel bridge 108. 1/10 chronograph intermediate wheel (a: the lower shaft part 2 7 1 b is rotatably integrated into the bottom support part 102t of the 1/10 chronograph intermediate wheel (A) provided on the main board 102. 1/10 count seconds The intermediate wheel (271 series rotatably configured rear wheel bridge 108 and the main plate 102 p 1/10 of the chronograph intermediate wheel (B) 272 includes an upper shaft portion 272a, a portion 272b, and a wheel portion 272d. 1/10 The chronograph intermediate wheel (B) 271 section 272d system is configured to mesh with the 271d of the 1/10 chronograph intermediate wheel (A) 271. The upper shaft of the 1/10 chronograph intermediate wheel (B) 272 is rotatable It is integrated into the upper support portion 108u of the 1/10 chronograph wheel (B) provided on the rear wheel bridge 108 (refer to the lower shaft portion of the 1/10 chronograph intermediate wheel (B) 272 shown in the rear wheel bridge described later). The 272b series can be rotated to 10 2U under the 1/10 chronograph intermediate wheel (B) provided on the main board 102 (refer to the diagram of the main board described later). Therefore, the (B) 272 series in the 1/10 chronograph can be rotated The rear wheel train bridged 108 and the spinner shape of the main board and the bottom pinion of the pinion of the lower shaft 27 1 Countdown: A) The wheel portion 272a of the lower shaft Middle) ° Intermediate bearing unit 102 -26- (23) (23) 200405146. Based on 1 / The 10-second counter (B) 272 rotates, and the 1 / 10-second counter wheel 274 is used to rotate. The mo-second counter wheel 274 includes an upper shaft portion 274a, a lower shaft portion 274b, and a wheel portion 274d. The wheel portion 274d of the second wheel 274 is configured to mesh with the wheel portion 272d of the 1 / 10th chronograph intermediate wheel (B) 272. The upper shaft portion 274a of the 1 / 10th second wheel 274 is rotatably integrated to be provided at The upper support portion 108v of the 1 / 10th chronograph wheel of the rear wheel bridge 108 (refer to the figure of the rear wheel bridge hereinafter described). The lower shaft portion 274b of the 1 / 10th chronograph wheel 274 is rotatably integrated with the main shaft 102 The 1/10 countdown wheel lower support part 102v (refer to the diagram of the main board described later). Therefore, the 1/10 countdown wheel 274 is a rotatable rear wheel train bridge between 108 and the main board 102. 1 The / 1 10-second chronograph hand 2 7 5 series is attached to the 1/1 / 10-second chronograph wheel 2 74. 1/1 / 10-second chronograph 27 27 5 frame a 1/10 chronograph indicator. In the chronograph measurement mode The 1/10 seconds chronograph hand 2 7 5 is operated to indicate the "1/10 seconds" of the elapsed time. Referring to Fig. 1, the rotation center of the 1/10 second wheel 274 is arranged on the reference horizontal axis of the motherboard 3 0 4 Position above the center of the motherboard 3 0 0 and Between the outline portion 312 of the plate 102, the motherboard 102 is arranged on 12 o'clock direction of the timepiece 100 of the heart. The distance between the center of rotation of the 1/10 chronograph second wheel 274 and the center of the main board 300 is about 1/2 of the radius of the largest outer shape of the main board 102. (1. 5) Architecture of the motherboard The central tube 103 is provided at the center of the motherboard 3'0 of the motherboard 1'2 in Figures 1 to 4 '. The rotation center axis 130p of the positioning wheel 130 is disposed above the main board reference vertical axis 3 02 and between the main board center 3 00 and the main body 102's outline portion 03. The main board 102 is disposed at the center 100. O'clock -27 · (24) (24) 200405146 direction ,. The lower support part 102e of the split wheel is arranged in the second zone 3 2 0 of the main board 102. The rotation center of the positioning rod 134, the rotation center of the yoke 136, and The center of rotation of the positioning lever 1 40 is arranged in the second zone 3 2 0 of the main board 102. The second support part 02k of the chronograph wheel is arranged above the reference horizontal axis 3 04 of the main board and the main board center 3 00 and Between the external parts 306 of the main board 102, the main board 102 is arranged in the "6 o'clock direction" of the center 100. The lower support part 102a of the hour rotor (A) and the fifth wheel / pinion (A ) The lower support portion 102b is arranged in the third area 330 in the main board 102. The rotor lower support portion 102f counts hours / minutes, the fifth wheel / pinion support portion 102g, counts seconds Bottom support part 102h of the middle wheel (A), 102j bottom support part of the chronograph middle wheel (B), 102m of bottom support part of the scoring middle wheel (A), and scoring device The lower supporting part 102η of the intermediate wheel (B) is arranged in the third zone 330 of the main board 102. The lower supporting part 102ρ of the scoring wheel is arranged above the main board reference vertical axis 3 02 and at the center of the main board 3 00 Between the main part 102 and the external part 309 of the main board 102, the main board 102 is arranged in the "9 o'clock direction" of the core 100. The side support third wheel / pinion (A) The lower support part 102d is the fourth arranged in the main board 102 Zone 340. 1/10 second rotor lower support part 102r, 1/10 second fifth wheel / pinion lower support part 102s, 1/10 second counter middle wheel (A) lower support part 102t and 1 / The lower support part 1011 of the 10-second counter wheel (B) is arranged in the fourth zone 340 of the main board 102. The lower support part 10 / 10v of the second chronograph wheel is arranged above the reference horizontal axis 304 of the main board. And between the main board center 3 00 and the outer shape of the main board 102 -28- (25) (25) 200 405 146 3 1 2, the main board 10 02 is arranged at the center of the 100, '1 2 o'clock direction'. · (1. 6) Gear train bridging (A) and gear train bridging (B) refer to Figures 1 and 5. In the gear train bridging (A) 106, the second wheel / pinion upper shaft portion 106c is arranged on the side. Motherboard center 3 00. The upper support portion 106e of the split wheel is arranged in the second zone 3 of the gear train bridge (A) 106. The 20 ° time support (0 6a) on the rotor (A) and the fifth wheel / pinion (A) The support portion 106b is a third zone 3 3 0 arranged in the wheel train bridge (A) 106. Hour-minute / second rotor upper support part 107f and hour-minute / second fifth wheel / pinion upper support part 107g are arranged in the third zone of the gear train bridge (B) 107. The third wheel is located on the 3 3 0 ° side. The upper support portion 106 d of the pinion (A) is a fourth region 340 arranged in the gear train bridge (A) 106. 1/10 second rotor upper support part 106r and 1/10 second fifth wheel / pinion upper support part 106s are arranged in the fourth zone of the gear train bridge (A) 106 after 3 40 ° (1 · 7) For the architecture of the wheel train bridge, refer to FIGS. 1 and 6. In the rear wheel train bridge 108, the center hole 108CH is located at the center of the motherboard 300. The support part 108k of the chronograph wheel is arranged in the rear wheel bridge 108, which is located above the main board reference horizontal axis 304 and between the main board center 300 and the outer part of the rear wheel bridge 108. The rear wheel bridge 1 08 is arranged in the "6 o'clock direction" of the center 100.

-29- (26) (26) 200405146 1 08h on the chronograph intermediate wheel (A), 108j on the chronograph intermediate wheel (B), 108m on the chronograph intermediate wheel (A), and The upper support portion 108n of the scorer intermediate wheel (B) is arranged in the third zone 330 in the rear wheel train bridge 108. The support part 108ρ on the scoring wheel is located in the rear wheel bridge 108, which is located above the main board reference vertical axis 3 02 and between the main board center 300 and the outer part of the rear wheel bridge 108. The rear wheel bridge 1 08 is arranged in the "9 o'clock direction" of the center 100. The upper support portion 108t of the 1/10 chronograph intermediate wheel (A) and the upper support portion 108u of the 1/10 chronograph intermediate wheel (B) are arranged in the fourth zone 340 of the rear wheel bridge 108. The support unit 108v on the 1/10 second wheel is arranged at the position of the rear wheel bridge 108, which is located above the main board reference horizontal axis 3 04 and between the center of the main board 300 and the outer shape of the rear wheel bridge 108. The rear wheel bridge 108 is arranged in the "12 o'clock direction" of the center 100. (1. 8) The preferred arrangement of the components in the core 100 will be explained. Referring to FIG. 1, on the surface side of the core 100, the rotation center 134c of the positioning lever 134, the rotation center 136c of the yoke 136, and the rotation center 140c of the repositioning lever 140 are arranged in the second region 320. The yoke 136 is preferably manufactured by, for example, elastic deformation of stainless steel. The spring portion of the yoke 1 3 6 is arranged in the second region 3 2 0 on the surface side of the core 100. With the structure in this manner, the long spring can be efficiently arranged on the surface side of the core. The crystal units 114 and 1C (Integrated Circuit) 1 16 are arranged in the second region 320 on the surface side of the core 100. With the structure in this way, the water -30- (27) (27) 200405146 crystal units 1 1 4 and 1C (integrated circuit) 1 1 6 can be efficiently disposed on the surface side of the core. As a modified example, the crystal unit 1 1 4 may be disposed in the first area 3 1 0 on the surface side of the epicenter 100. As a modified example, 1C (Integrated Circuit) 1 1 6 may be arranged in the first region 3 1 0 on the surface side of the epicenter 100. The position of the repositioning lever 140 for positioning the fifth wheel / pinion (A) 220 is a third zone 3 3 0 disposed on the surface side of the core 100. The position of the repositioning lever 140 for performing the repositioning operation is the second zone 3 20 disposed on the surface side of the core 100. With the structure in this manner, the reposition lever 1 40 having a long spring portion can be efficiently disposed on the surface side of the core. The center of the battery 120 may be arranged in the first region 3 1 0 on the surface side of the epicenter 100. However, the center of the battery 120 may be disposed in the fourth region 340 on the surface side of the epicenter 100. That is, although the center of the battery 120 may be disposed in the first region 310 or the fourth region 340, the battery 120 is configured to overlap the outer portion 3 12 located between the first region 3 10 and the fourth region 340. With the structure in this manner, the battery 120 having a large size can be efficiently disposed on the surface side of the epicenter 100. The center 242c (hereinafter referred to as the "coil block center") of the central axis line in the singing direction of the coil wire winding portion of the time coil block 242 may be disposed at the center of the main board 300. The rotation center of the time rotor (A) 246 and the rotation center of the time fifth wheel / pinion (A) 220 can be arranged at the center of the main board 300. The rotation center of the side third wheel / pinion 222 may be arranged in the fourth zone 340. The rotation center of the minute wheel 226 may be arranged in the second zone 3-20. The coil block center 262c of the hour / minute / second coil block 262 may be arranged in the -31-(28) (28) 200405146 third zone 3 3 0. Hours / minutes / seconds rotation center of rotor 2 66, Hours / minutes / second fifth wheel / pinion 2 50 0 rotation centers, seconds counter intermediate wheel (a) 2 5 1 rotation centers, scoring intermediate wheel The rotation center of (A) 2 5 2, the rotation center of the chronograph intermediate wheel (B) 2 5 3, and the rotation center of the chronograph intermediate wheel (B) 2 5 7 may be arranged in the third zone 330. In the third area 330, the coil block center 262c of the hour / minute / second coil block 262 is disposed outside the coil block center 2 4 2 c of the time coil block 2 4 2. In the third zone 3 3 0, the rotation center of the hour / minute rotor 266 is arranged on the outside of the rotation center of the time rotor (A) 246. The rotation center of the chronograph wheel 2 5 4 is located above the reference horizontal axis 3 04 of the main board and between the main board center 3 00 and the outer part 3 06 of the main board 102. The main board 102 is arranged at the center of the watch at 6 o'clock. direction". The distance between the rotation center of the chronograph wheel 254 and the center of the main board 300 is preferably 30% to 70% of the radius of the largest external shape of the main board 102, and more preferably 45% to the radius of the largest external part of the main board 102 55% is particularly preferably 1/2 of the radius of the largest outer shape of the main board 102. In addition, the rotation center of the scoring wheel 258 is disposed above the main board reference vertical axis 302 and between the main board center 300 and the main body 102's outline portion 09, and the main board 102 is placed at the center 100 of the "9" O'clock. " The distance between the center of rotation of the scoring wheel 25 8 and the center of the main board 3 00 is preferably 30% to 70% of the radius of the largest outline of the main board 102, and more preferably 4% of the radius of the largest outline of the main board 102. 5% to 5 5% 'and, particularly preferably, it is 1/2 ° of the radius of the largest outer shape of the main board 102. The coil center 2 8 2 of the coil block 2 8 2 can be arranged in the fourth ( 29) (29) 200 405 146 zone 340. 1/10 second rotation center of rotor 286, 1 / io second rotation center of fifth wheel / pinion 2 7 0, i / 丨 ○ chronograph intermediate wheel (a) 2 7 The center of rotation of 1 and the center of rotation of the 1/10 chronograph intermediate wheel (B) 272 can be arranged in the fourth zone 3 40. With the structure in this manner, the plurality of coil blocks and the plurality of wheel trains can be efficiently arranged on the surface side of the core. Here, the number of components of the structure gear train is not limited to the above, however, one or more transmission wheels may be additionally added. The rotation center of the 1/10 second wheel 274 is arranged above the reference horizontal axis 3 04 of the main board and between the main board center 3 00 and the outline part 3 12 of the main board 102. The main board 102 is arranged at the core 100, 12 The direction of the clock. "The distance between the center of rotation of the 1 / 10th second wheel 274 and the center of the motherboard 300 is preferably 30% to 70% of the radius of the largest shape of the motherboard 102, and more preferably the motherboard 102. 45% to 55% of the radius of the largest outline part, and particularly preferably 1 1/2 of the radius of the largest outline part of the main board 102. Preferably, the rotation center of the second wheel 2 5 4 and the main board center 30 The distance between 0, the center of rotation of the scoring wheel 258 and the center of the main board 300, and the distance between the center of rotation of the 1/10 chronograph wheel 274 and the center of the main board 3,000 are all equal. (1 9) Operation of the first embodiment Next, the operation of the first embodiment of the analog electronic watch (pointer chronograph) according to the present invention will be explained. Referring to FIG. There is a housing 200. The crown 100 and the dial 104 are housed in a housing 202. The crown 200 is provided on the housing 202 to adjust Rotate the pointer positioning lever 1 1 〇. Side -33- (30) (30) 200405146 The time of the chronograph can be set by pulling the crown 204 to the first stage and rotating the crown 204. That is, when the crown When 204 is pulled out to the first stage, the second hand 234 is stopped, and the hour hand 23 0 and the minute hand 2 3 2 can be rotated by rotating the crown 2 0 4. The housing 202 is provided for starting and stopping the operation of the chronograph. Start / stop button 206. When the start / stop button 206 is pressed, the spring system structure is switched to drive the signal related to the start operation or stop operation to the IC 1 1 6. The housing 2 0 2 is provided with a The reset button 208 of the chronograph operation is set on the setting side. When the reset button 208 is pressed, the spring system structure is switched to drive the signal related to the reset operation of the chronograph to IC116. Here, the current explanation Indicated operation. Referring to Figures 1 to 3, Figures 7 and 8, the time of the side counter is set by pulling the crown 204 to the first stage and rotating the crown 204 to set the current time, and the crown 204 is pushed To the 0th stage, and the side uses the second wheel / pinion 2 2 1 series through time the fifth wheel / The rotation of the pinion (A) 220 is based on the rotation of the time rotor (a) 246. The second side wheel / pinion 2 2 1 series rotates once per minute, so 'attach to the side first wheel / small The second hand 2 3 4 of the gear 2 2 1 indicates the “second” of the current time. Furthermore, the rotation of the side sun gear / pinion 224 is via the third wheel / pinion 2 2 2 of the side. The pinion 2 2 1 rotates. The side sun gear / pinion 2 2 4 rotates once per hour, so the minute hand 23 2 of the side hollow shaft pinion 224 b attached to the side sun wheel / pinion 224 indicates the “minute” of the current time. In addition, the rotation of the hour wheel 2 2 8 via the minute wheel 2 2 6 is based on the rotation of the side center -34- (31) (31) 200405146 and the rotation of the pinion 2 2 4. The hour wheel 2 2 8 rotates once every 12 hours, so the second hand 2 3 4 attached to the hour wheel 2 2 8 represents the current time, and the hour. ”Next, the operation of measuring and recording will be explained. Refer to the figure 8. At the stage where the chronograph stops measuring and resetting, all the minute chronograph hands 2 5 9, the second chronograph hands 2 5 5 and 1/1 〇 second chronograph hands 2 7 5 are arranged in the zero position (starting position)". That is, during the reset phase, all the minute hand 2 5 9, second hand 25 5 and 1/10 second hand 275 are arranged at the position indicating “zero”. Referring to FIGS. 1 to 3, FIG. 7 and 8. When the start / stop button 206 is pressed to start measuring this chronograph, the chronograph measurement mode is activated. In the chronograph measurement mode, the chronograph minute / second rotor 266 is rotated, and the chronograph minute / second fifth wheel / pinion 250 is rotated based on the rotation of the chronograph minute / second rotor 266. Moreover, the chronograph intermediate wheel (A) and the scoring intermediate wheel (A) 252 are rotated based on the rotation of the fifth wheel / pinion 2 50 of the hour / minute. The chronograph wheel 25 4 is rotated based on the rotation of the chronograph intermediate wheel (B) 25 3 through the chronograph intermediate wheel (B) 25 3. In the chronograph measurement mode, the second chronograph hand 25 5 attached to the chronograph wheel 254 indicates the "second" of the elapsed time. The scoring wheel 2 5 8 is rotated based on the rotation of the scoring intermediate wheel (B) 25 7 based on the rotation of the scoring intermediate wheel (A) 2 5 2. In the chronograph measurement mode, the minute chronograph hand 25 9 attached to the scoring wheel 2 5 8 indicates the "minute" of the elapsed time. Furthermore, in the chronograph measurement mode, the rotor 286 series rotates in 1 / 10th of a second, and the fifth wheel / pinion 270 series in 1/10 seconds is based on • 35- 220 (32) of 1Π0 seconds rotor 2 8 6 (32) 200405146 Rotate and rotate. The 1/10 chronograph intermediate wheel (B) 272 is rotated by the rotation of the 1/10 chronograph intermediate wheel (A) 271 based on the rotation of the fifth wheel / pinion 270 in 1/10 second. The 1 / 10th chronograph wheel 274 is rotated based on the rotation of the 1 / 10th chronograph intermediate wheel (B) 2 7 2. In the chronograph measurement mode, attached to the 1/10 countdown wheel 2 7 4 1/10 seconds chronograph hand 2 7 5 series operation, in units of 1/10 seconds "to indicate the elapsed time" Seconds ". In the chronograph measurement mode, when the start / stop button 206 is pressed further, the chronograph measurement can be stopped. During the phase of stopping the chronograph measurement, the minute hand 2 5 9 It stops at the phase indicating the elapsed time, the minutes, seconds, the second chronograph hand 2 5 5 stops at the phase indicating the elapsed time, the second "phase, and the 1/10 seconds chronograph hand 2 7 5 stops at the "1/10 seconds unit, indicating the" second "phase of the elapsed time. When the reset button 2 0 8 is pressed to stop the chronograph measurement phase, all minute chronograph hands 2 5 9 and second chronograph hands 2 5 5 and 1/10 seconds hand 2 7.5 returns to the position indicating “zero” (refer to FIG. 8). (2) Second Embodiment Next, a second embodiment of the present invention will be explained. The second embodiment is a "central chronograph" of an analog electronic watch, that is, an analog chronograph having the following structure, wherein the chronograph second hand is arranged at the center of the watch The small second hand indicating the time is arranged at a position other than the center of the center of the watch. The following will mainly explain the differences between the second embodiment of the present invention and the first embodiment of the present invention. In the content of the description, the above explanation of the first embodiment of the present invention will be applied to it. -36-(33) (33) 200405146 (2 · 1) The table of the pointer chronograph according to the present invention will be explained The overall structure of the heart. Referring to FIGS. 9 to Π, the analog chronograph of the present invention is provided with a watch core 400. The watch core 4 is provided with a main board 102 with a substrate for constructing the watch core 400, and a wheel bridge (A) 1 0 6. Gear train bridge (B) 107 and rear gear train 108. Main board 102, gear train bridge (A) 106, gear train bridge (B) 107 and rear gear train 108 are the same as The main board 102, the wheel train bridge (A) 106, the wheel train bridge (B) 107, and the rear wheel train bridge 108 used in the aforementioned table core 100. (2. 2) Indicate the structure of the train department. The receiver 'will explain that the time refers to the structure of the train department. The time indicating gear train includes a motor for driving the time indicating gear train and a time indicating gear train. Referring to FIGS. 9 to 11, the surface of the core 400 is provided with a circuit block, a battery 120, a center time wheel section, a chronograph / minute wheel section, and a 1/5 second wheel train. And switching devices. The center wheel / pinion for the center 4 2 4 series can be rotatably integrated into the center hole of the center tube 103. The center wheel / pinion 4 2 4 for the center includes: a center wheel 4 2 4 a for the center and a hollow shaft pinion 4 2 4 b for the center. The center sun wheel / pinion 424 used for the center 400 is the same as the middle seventh, wheel / pinion 2 2 4 used for the side of the center 100 described above. The center time gear train includes a motor for driving the time gear train, that is, a center time motor, and a center time gear train. The center uses the time wheel train mechanism to rotate by the rotation of the center time motor. Therefore, the current time "hour" is indicated by the hour hand 230, the "minute" of the current time is indicated by the minute hand 232, and the second hand (ie , Small second hand) 4 3 4 represents the "second" of the current time. -37- 222 (34) (34) 200405146 The center time motor includes: the center time coil block 4 8 2. the center time stator 484 and the center time rotor, that is, the time rotor (B) 486. The center time coil block 4 82, the center time stator 484 and the time rotor (B) 4 8 6 are the same as the 1/10 second coil block 282 and 1/10 second stator 284 used in the above-mentioned core 100. And 1/10 second rotor 2 8 6 components. When the time motor drive signal output from 1C (Integrated Circuit) 116 is input to the time coil block 242, the center time stator 484 is magnetized to rotate the time rotor (B) 486. According to 1C (Integrated Circuit) 116, 1C of the side chronograph and 1C of the center chronograph can be manufactured separately, or the signal 1C can be used separately by switching the conductive stages of the two function setting terminals. Two functions, the same 1C constitutes 1C of the side chronograph and 1C of the center chronograph. For example, the embodiment of the present invention can be structured such that 1C (Integrated Circuit) 1 16 is provided with a terminal TS for a side chronograph and a terminal TC for a center chronograph, and when the terminal TS is When connected to the positive electrode of the battery 120, the IC1 16 series operates as 1C of a chronograph on the side, and when the terminal TC connects to the positive electrode of the battery 120, the IC1 16 series operates as 1C of a chronograph on the center. That is, according to the embodiment of the present invention, the IC of the side watch is the same as the IC of the center watch. Time rotator (B) 4 8 6 series architecture to rotate, for example, 180 degrees per second. The time rotor (B) 486 includes an upper shaft portion 486a, a lower shaft portion 486b, a pinion gear portion 486c, and a rotor magnet 486d. The upper shaft portion 486a of the time rotor (B) 486 is rotatably integrated with the support portion 106a of the time rotor (B) provided on the wheel bridge (A) 106. The upper support portion 106a of the time rotor (B) is the same as the upper support portion 106a of the time rotor (A) used for the above-mentioned core 100 as described in (38) (35) (35) 200405146. The lower shaft portion 486b of the time rotor (B) 486 is rotatably integrated with the lower support portion 102a of the time rotor (B) provided on the main plate 102. The lower support part 102a of the time rotor (B) is the same as the lower support part 102a of the time rotor (A) used in the above-mentioned epicenter 100. Therefore, the time rotor (B) 486 series is rotatably arranged between the gear train bridge (A) 106 and the main plate 102. The center uses the time fifth wheel / pinion gear, that is, the time fifth wheel / pinion gear 42 0, and the system is rotated based on the rotation of the time rotor (B) 4 8 6. The fifth wheel / pinion (B) 420 used for the time of the core 400 is the same as the fifth wheel / pinion 270 of the 1/10 second used for the above-mentioned core 100. Time The fifth wheel / pinion (B) 420 includes an upper shaft portion 420a, a lower shaft portion 420b, an upper pinion portion 420c, a wheel portion 420d, and a lower pinion portion 42 Of. The wheel portion 420d of the time fifth wheel / pinion (B) 420 is configured to mesh with the pinion portion 486c of the time rotor (B) 486. The upper shaft portion 420a of the time fifth wheel / pinion (B) 420 is rotatably integrated with the time fifth wheel / pinion (B) upper support portion 106s provided at the wheel bridge (A) 106. The time of the fifth wheel / pinion (B) upper support portion 106s is the same as the fifth wheel / pinion upper support portion 106s used for the 1/10 second of the above-mentioned center 100. Time The fifth shaft / pinion (B) 4 2 0's lower shaft portion 4 2 0 b is rotated and integrated into the fifth wheel / pinion (B) lower support portion 1 0 2 s provided on the main board 10 2. Used at the time of the center of the center 4 0 0 The fifth wheel / pinion (B) lower support portion 10 2 s is the same as the above-mentioned center of the center 1 〇 1 / [5 seconds fifth wheel / pinion lower support 102s. Therefore, the time fifth wheel / pinion (B) 420 series can be rotatably arranged between the wheel train bridge (A) 106 and the main board 102. -39- 224 (36) (36) 200405146 The center fourth wheel / pinion 4 2 1 and the middle small seconds wheel 4 3 2 system are structured to rotate based on the rotation of the fifth wheel / pinion (B) 420 of time. The center fourth wheel / pinion 421 includes an upper shaft portion 421a, a lower shaft portion 421b, a pinion portion 421c, and a wheel portion 421d. The center uses a wheel portion 421d system of the fourth wheel / pinion 421 to mesh with the upper pinion portion 420c of the time fifth wheel / pinion (B) 420. The upper shaft portion 421a of the center fourth wheel / pinion 421 is rotatably integrated with the center fourth wheel / pinion upper support portion 106c provided at the wheel bridge (A) 106. Therefore, the center fourth wheel / pinion 421 train is rotatably disposed between the train bridge (A) 106 and the main plate 102. The center sun gear / pinion 424 system is configured to rotate via the rotation of the center fourth wheel / pinion 421 via the center third wheel pinion 422. The third wheel pinion 422 for the center includes an upper shaft portion 422a, a lower shaft portion 422b, a pinion portion 422c, and a wheel portion 422d. The wheel portion 422d of the third wheel pinion 422 for the center is meshed with the pinion portion 421c of the fourth wheel / pinion 421 for the center. The upper shaft portion 4 2 2 a of the center third pinion 422 is rotatably integrated with the center third wheel / pinion upper support portion 10 6 d c provided on the wheel bridge (A) 106. The lower shaft portion 422b of the center third wheel pinion 4 2 2 is rotatably integrated with the center third wheel / pinion lower support portion 10 2 d c provided on the main board 102. Therefore, the center third wheel pinion 422 train is rotatably disposed between the train wheel bridge (A) 106 and the main plate 102. The center uses a center wheel / pinion 4 2 4 series structure to make one rotation per hour. The minute hand 2 3 2 series is attached to the center sun gear / pinion 4 2 4 for the center hollow shaft pinion 424b ° -40- (37) (37) 200405146 The hour wheel 228 series mechanism is based on the rotation of the minute wheel 226 based on The center sun wheel / pinion 424 rotates to rotate. The minute wheel 226 and the time wheel 228 used for the watch core 400 are the same as the minute wheel 226 and the time wheel 228 used for the watch core 100, respectively. The center of rotation of the hour wheel 228 is arranged at the same position as the center of rotation of the side wheel / pinion 224. However, the center of rotation of the center fourth wheel / pinion 421 is arranged at a position different from the center of rotation of the side center wheel / pinion 224. The hour wheel 228 is structured to rotate once every 12 hours. The middle small seconds wheel (A) 43 2 series architecture rotates based on the rotation of the fifth wheel / pinion (B) 420 of time. The middle small seconds wheel (A) 432 includes: an upper shaft portion 43 2a, a lower shaft portion 43 2b, and a wheel portion 43 2d. The middle small second wheel (A) 432 has a wheel portion 2 2d structure to mesh with the lower pinion portion 420f of the time fifth wheel / pinion (B) 420. The upper shaft portion 43 2a of the middle small seconds wheel (A) 432 is rotatably integrated with the upper small portion 108t of the middle small seconds wheel (A) provided at the rear wheel bridge 108. The upper supporting part 108t of the middle small seconds wheel (A) used for the epicenter 400 is the same as the upper supporting part 108t of the middle wheel (A) of the 1/10 stopwatch used for the above-mentioned epicenter 100. The lower shaft portion 43 2b of the middle small seconds wheel (A) 432 is rotatably integrated with the lower support portion 102t of the middle small seconds wheel (A) provided on the main plate 102. The lower supporting part 102t of the middle small seconds wheel (A) used in the epicenter 400 is the same as the lower supporting part 102t of the 1 / 10th chronograph intermediate wheel (A) used in the above-mentioned epicenter 100. Therefore, the middle small seconds wheel (A) 432 is rotatably disposed between the rear wheel bridge 108 and the main board 102. The small seconds wheel 4 3 6 series architecture rotates based on the rotation of the middle small seconds wheel (A) 432 via the rotation of the middle small seconds wheel (B) 4 3 4 -41-(38) (38) 200405146. The middle small seconds wheel (A) 4 3 2 has the same size and shape as the middle small seconds wheel (b) 434. Furthermore, the size and shape of the middle small seconds wheel (b) 43 4, the size and shape of the middle small seconds wheel (B) 434, the size and shape of the middle wheel (A) 2 5 1 and the middle of the seconds The size and shape of the wheel (b) 2 5 3 are the same. The middle small seconds wheel (B) 4 3 4 includes an upper shaft portion 4 3 4 a, a lower shaft portion 43 4b, and a wheel portion 434d. The middle small second wheel (B) 43 4 has a wheel part 4 4d system which is configured to mesh with the middle small second wheel (A) 4 3 2 wheel part 4 3 2 d. The upper shaft part 434a of the middle small seconds wheel (B) 434 is rotatably integrated with the upper support part 108 of the middle small seconds wheel (B) provided at the rear wheel bridge 108. The upper support portion 108u of the middle small seconds wheel (B) used for the epicenter 400 is the same as the 108U upper support portion of the middle wheel (B) of the 1 / 10th chronograph used in the above-mentioned epicenter 100. The lower shaft portion 434b of the middle small seconds wheel (B) 434 is rotatably integrated with the lower support portion 102u of the middle small seconds wheel (B) provided on the main board 102. The lower supporting part 102u of the middle small seconds wheel (B) used in the epicenter 400 is the same as the lower supporting part 102u of the middle wheel (B) of the chronograph 1/10 used in the epicenter 100 above. Therefore, the middle small seconds wheel (B) 434 is rotatably arranged between the rear wheel train bridge 108 and the main board 102. The small seconds wheel 43 6 includes an upper shaft portion 436a, a lower shaft portion 43 6b, and a wheel portion 43 6d. The wheel portion 43 6d of the small seconds wheel 436 is configured to mesh with the wheel portion 434d of the middle small seconds wheel (B) 43 4. The upper shaft portion 43 6a of the small seconds wheel 43 6 is rotatably integrated with the small seconds wheel upper support portion 108 volt provided on the rear wheel bridge 108. The small support wheel 108v used for the epicenter 400 is the same as 42- (39) (39) 200405146 The 1/10 second support wheel 102v used for the above-mentioned core 100. The lower shaft part 436b of the small seconds wheel 436 is rotatably integrated with a small seconds wheel lower support part 102v provided on the main board 102. The small second wheel supporting part 10 2 v used for the epicenter 400 is the same as the i / 丨 0 second wheel supporting part 10 2 v used for the above-mentioned center 100. Therefore, the small seconds wheel 4 3 6 series is rotatably arranged between the rear wheel train bridge 108 and the main board 102. The small seconds hand 4 3 8 series is attached to the small seconds wheel 43 6. Small second hand 43 8 frame one second indicating component. Referring to FIG. 9, the rotation center of the small seconds wheel 4 3 6 is disposed above the reference horizontal axis 3 04 of the main board and between the main board center 3 00 and the outer portion 3 1 2 of the main board 102. The main board 10 02 is disposed at the center of the table. The distance between the center of rotation of the small second wheel 4 3 6 in the "12 o'clock direction" of 100 and the center of the main board 300 is about 1/2 of the radius of the largest outer shape of the main board 102. Referring to FIGS. 9 and 11 ′ the reposition lever 140 ′ includes a reposition conductive spring 140 d for performing a reset operation, a wheel train relocation lever holding portion 1 4 2 for holding the wheel train positioning lever 440, and a wheel for operating the wheel. The operating spring 143 of the positioning lever 4 4 0. The center of rotation of the reposition lever 140 'can be made the same as the center of rotation of the reposition lever 140 used for the above-mentioned center 100, except that the wheel train positioning portion 140f is not provided. At the stage of pulling the pointer positioning lever 1 1 0 to the first stage, the pointer type chronograph can be reset from the repositioning conductive spring 1 4 0 d of the conductive repositioning lever 1 4 0 'to the repositioning pattern of the circuit block. Positioning. At the stage where the pointer positioning lever 1 110 is pulled out to the first stage, the gear train positioning lever 4 4 0 can position the rotation of the middle small seconds wheel (B) 4 3 4 based on the operation of the repositioning lever 1 4 0 ′. The gear train positioning lever 440 includes a guide window portion 440f and 440g with a long hole, an operation window portion 440h which is inserted by an operation spring 143 resetting 43-228 (40) (40) 200405146 position lever 140 ', and is used for positioning. Rotating wheel train positioning portion 440k of the middle small seconds wheel (B) 43 4. The main board 102 is provided with two guide pins 170P and 172p inserted into the guide window portions 440f and 440g of the gear train positioning lever 440, respectively. The guide window portion 44 Of of the wheel train positioning lever 440 is guided by the guide pin 170p of the main board 102. The guide window portion 440g of the gear train positioning lever 440 is guided by the guide pin 172p of the main plate 102. Therefore, the gear train positioning lever 440 is integrated to the main board 102 so as to move linearly with respect to the main board 102. The wheel train positioning lever 440 is arranged so as not to overlap the battery 120. In addition, the wheel train positioning lever 440 is a member that does not overlap with the pointer. The operation window portion 440h of the gear train positioning lever 440 is inserted with the operation spring 143 of the reposition lever 140. When the pointer positioning lever 110 is pulled out to the first stage, the repositioning lever 140 'is rotated. When the repositioning lever 14 is rotated by the rotation of the operation spring 143, the gear train positioning lever 440 can be linearly moved by the guide pins 170p and 172p. When the train wheel positioning lever 44 0 linearly moves, the train wheel positioning portion 440k of the train wheel positioning lever 440 can set the rotation of the middle small seconds wheel (B) 4 3 4. (2 · 3) The structure of the chronograph hour / minute indication gear train section then 'operates the narration to operate the chronograph measurement mode on the chronograph / minute indicator of the analog electronic watch (pointer chronograph) according to the present invention. Gear department. The chronograph / minute indicator train section includes a motor for driving the chronograph / minute indicator train and a chronograph / minute indicator train. Referring to FIG. 9 'The chronograph hour / minute indicating gear train includes a motor for driving the chronograph hour / minute indicating gear train, that is, a chronograph hour / minute motor and a chronograph hour 7-44- (41) (41) 200405146 indicates the gear train. The chronograph hour / minute indicates the gear train architecture to rotate by the rotation of the chronograph hour / minute motor. The chronograph minute hand indicates the "chronograph minute," and The chronograph hand indicates "chronograph," which measures the elapsed time in the chronograph measurement mode. In the chronograph measurement mode, [C (Integrated Circuit) 1 1 6 series architecture measures the elapsed time and operates the chronograph hour / minute motor. The chronograph hour / minute motor includes a chronograph hour / minute coil block 462, a chronograph hour / minute second stator 464, and a chronograph hour / minute rotor 466. The chronograph hour / minute coil block 462, the chronograph hour / minute second stator 464, and the chronograph hour / minute rotor 4 6 6 used in the watch core 400 are respectively the same as the chronograph minutes used in the aforementioned watch core 100. Coil block 2 6 2, hour / minute stator 2 6 4 and hour / minute rotor 2 6 6 components. When the chrono / minute motor drive signal output by 1C (Integrated Circuit) 116 is input to the chrono / minute / second coil block 462, the chrono / minute stator 4 64 is magnetized to rotate the chrono / minute Rotor 466. The chronograph hour / minute rotor 466 system is configured to rotate, for example, 180 degrees per minute. Hours, minutes, seconds, rotor 4 6 6 can also be structured to 180 degrees every 10 seconds, 20 seconds or 30 seconds. The chronograph / minute rotor 466 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a rotor magnet. The upper shaft portion of the chronograph / minute rotor 466 is rotatably integrated with the chronograph / minute rotor upper support portion 107f provided at the wheel train bridge (B) 107. The chronograph hour / minute rotor upper support portion 107f used in the core 400 is the same as the chronograph minute / second rotor upper support portion 107f used in the above-mentioned core 100. The lower shaft portion of the chronograph / minute rotor 466 is rotatably integrated with the chronograph / minute rotor lower support portion 102f provided on the main plate 102. The chronograph hour / minute rotor lower support used for the core 400 -45- (42) (42) 200405146 The receiving portion 102f is the same as the chronograph minute / second rotor lower support portion 102f used in the above-mentioned core 100. Therefore, the chronograph hour / minute rotor 466 is rotatably arranged between the wheel train bridge (B) 107 and the main plate 102. The chronograph hour / minute fifth wheel / pinion 450 system is configured to rotate based on the rotation of the chronograph hour / minute rotor 466. The scoring intermediate wheel (C) 451 and the chronograph intermediate wheel (A) 452 are structured to rotate based on the rotation of the chronograph / minute fifth wheel / pinion 450. The hour / minute fifth wheel / pinion gear 450 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a wheel portion. The wheel portion of the chronograph / minute fifth wheel / pinion 4 50 meshes with the small tooth portion of the chronograph / minute rotor 4 6 6. The upper shaft of the hour / minute fifth wheel / pinion gear 450 can be rotatably integrated with the hour / minute fifth wheel / pinion upper support portion 107g provided at the wheel bridge (B) 107. Chronograph hour / minute fifth wheel / pinion gear upper support part 107 used in the core 400 Same as the chronograph minute / second fifth wheel / pinion gear upper support part used in the epicenter 100 0 above 107g. The lower shaft of the hour / minute fifth wheel / pinion 45 0 is rotatably integrated with the hour / minute fifth wheel / pinion lower support portion 102 g provided on the main board 102. The chronograph hour / minute fifth wheel / pinion lower support portion 102g used for the epicenter 400 is the same as the chronograph minute / second fifth wheel / pinion lower support portion 102g used in the above-mentioned epicenter 100. Therefore, the chronograph / minute fifth wheel / pinion 450 series is rotatably disposed between the wheel series bridge (b) 107 and the main board 102. The scoring wheel 454 is configured to rotate via the rotation of the scoring intermediate wheel (d) 45 3 based on the rotation of the scoring intermediate wheel (C) 4 5 1. The size and shape of the scoring intermediate wheel (C) 4 5 1 are the same as the size and shape of the scoring intermediate wheel (0) 4 5 3. Furthermore, the center of rotation of all the scoring intermediate wheels (c) 4 5 1 -46-(43) 200405146, the center of rotation of the scoring intermediate wheel (D) 4 5 3, and the middle of the chronograph (A) The rotation center of 2 5 1 and the rotation center of the chronograph intermediate wheel (B) 2 5 3 are the same. The scorer intermediate wheel (c) 451 includes an upper shaft portion, a lower shaft portion, and a wheel portion. The scoring intermediate wheel (C) 4 5 1 has a wheel system structure that meshes with the small teeth of the chronograph / minute brother fifth wheel / pinion 450. The upper shaft of the delta intermediate wheel (C) 45 1 is rotatably integrated with the upper support portion 108 h of the scorer intermediate wheel (C) provided on the rear wheel bridge 108. The scorer 108h on the middle wheel (C) of the scoring device used for the core 400 is the same as the support 108h on the middle wheel (A) of the chronograph chronograph used in the above-mentioned center 100. The lower shaft of the scorer intermediate wheel (C) 451 is rotatably integrated with the scorer intermediate wheel (C) lower support portion 102h provided on the main plate 102. The scoring device for the center of the center 400. The lower support part 102h of the middle wheel (C) is the same as the support part 102h of the middle wheel (A) of the chronograph used for the above center 100. Therefore, the scorer intermediate wheel (C) 451 is rotatably arranged between the rear wheel train bridge 108 and the main board 102. Scorer intermediate wheel 102 Scorer intermediate wheel (D) 4 5 3 includes: an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel structure of the scorer intermediate wheel (D) 4 5 3 meshes with the wheel portion of the scorer intermediate wheel (C) 451. The upper shaft of the scorer intermediate wheel (D) 4 5 3 is rotatably integrated with the upper support part 108 of the scorer intermediate wheel (D) provided at the rear wheel bridge 108. The supporting part 1 on the scoring intermediate wheel (D) used in the epicenter 4 0 0 is the same as the supporting part 1 on the chronograph intermediate wheel (B) used in the above-mentioned epicenter 丨 〇〇 108 . The lower shaft of the scoring intermediate wheel (D) 4 5 3 is rotatably integrated to the lower support portion 1022 provided on the main board -47- (44) (44) 200405146 (D). The lower support part 102j of the scoring intermediate wheel (D) used in the epicenter 400 is the same as the lower support part 102j of the chronograph intermediate wheel (B) used in the above-mentioned epicenter 100. Therefore, the scorer intermediate wheel (D) 4 5 3 series is rotatably arranged between the rear wheel train bridge 108 and the main board 102. The scoring wheel 4 5 4 system is structured to rotate based on the rotation of the scoring intermediate wheel (D) 4 5 3. The scoring wheel 454 includes an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel structure of the scoring wheel 454 meshes with the wheel portion of the scoring intermediate wheel (D) 4 5 3. The upper shaft portion of the scoring wheel 454 is rotatably integrated with a scoring wheel upper support portion 108k provided on the rear wheel train bridge 108. The support portion 108k of the scoring wheel used for the core 400 is the same as the support portion 108k of the scoring wheel used for the above-mentioned core 100. The lower shaft portion of the scoring wheel 454 is rotatably integrated with the scoring wheel lower support portion 102k provided on the main plate 102. The scoring wheel lower support part 102k used for the epicenter 400 is the same as the chronograph wheel lower support part 102k used for the above-mentioned core 100. Therefore, the scoring wheel 4 5 4 series is rotatably arranged between the rear wheel bridge 108 and the main board 102. A scoring pin 4 5 5 (refer to a complete combination of drawings described later) is attached to the scoring wheel 4 5 4. Scoring device Pin 4 5 5 structure a minute time indicating component. In the chronograph measurement mode, the scoring needle 45-5 operates to indicate the "minutes" of the elapsed time. Referring to FIG. 9, the rotation center of the scoring wheel 454 is disposed above the reference horizontal axis 304 of the main board and between the main board center 300 and the outline portion 306 of the main board 102. O'clock. " The distance between the center of rotation of the scoring wheel 454 and the center of the main board 3 00 is about 1/2 of the radius of the largest external shape of the main board 102. -48- (45) (45) 200405146 The chronograph wheel 4 5 8 series architecture rotates through the rotation of the chronograph intermediate wheel (B) 4 5 7 based on the rotation of the chronograph intermediate wheel (A) 4 5 2 . The chronograph intermediate wheel (A) 452 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a wheel portion. Chronograph intermediate wheel (A) 4 5 2 The wheel part. The system is configured to mesh with the small teeth of the chronograph / minute fifth wheel / pinion 4 50. The upper shaft of the chronograph intermediate wheel (A) 452 is rotatably integrated to 108m of the upper support portion of the chronograph intermediate wheel (A) provided on the rear wheel bridge 108. The chronograph intermediate wheel (A) supporting part 108 m used in the watch center 400 is the same as the scoring center supporting part 108 m of the scoring intermediate wheel (A) used in the above-mentioned center 100. The lower shaft of the chronograph intermediate wheel (A) 4 5 2 is rotatably integrated into the bottom support part 102m of the chronograph intermediate wheel (A) provided on the main board 102. The chronograph intermediate wheel (A) supporting lower part 102m used in the table core 400 is the same as the scoring intermediate support (100) lower part of the center wheel (A) used in the aforementioned centerpiece 100. Therefore, the chronograph intermediate wheel (A) 4 5 2 series is rotatably arranged between the rear wheel bridge 108 and the main board 102. The chronograph intermediate wheel (B) 4 5 7 includes: an upper shaft portion, a lower shaft portion, a pinion gear portion, and a wheel portion. The chronograph intermediate wheel (B) 4 5 7 system is configured to mesh with the pinion portion of the chronograph intermediate wheel (A) 4 5 2. The upper shaft of the chronograph intermediate wheel (B) 4 5 7 can be rotatably integrated with the upper support part 1 0 8 η of the chronograph intermediate wheel (B) provided at the rear wheel bridge. The chronograph used in the center of the center 4 0 0 108η is the same as the support part 108 in the middle wheel (B) of the scoring center used in the above-mentioned center 100. The lower shaft portion of the chronograph intermediate wheel (B) 4 5 7 is rotatably integrated with the lower support portion 10 2 η of the chronograph intermediate wheel (B) provided on the main plate 102. Chronograph 2 used for the epicenter 4 0 0 2 34 -49- (46) 200405146 Lower supporting part of the intermediate wheel (B) 1 〇2 η is the same as used for the lower bearing of the intermediate wheel (B) of the scorer recorded above部 1 0 2 η. Therefore, the chronograph wheel (B) 4 5 7 series is rotatably arranged between the rear wheel bridges 108 and 3. The chronograph wheel 45 8 includes an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel structure of the wheel 4 5 8 is to mesh with the scorer intermediate wheel (B) 2 5 7. The upper shaft portion of the chronograph wheel 45 8 is rotatably integrated with a chronograph wheel upper support portion 〇 08ρ provided on the bridge 108. Used for the support part 1 08p on the chronograph wheel is the same as used for the support part 10 8ρ on the centerpiece scoring wheel. The lower shaft portion of the chronograph wheel 4 5 8 is integrated into the chronograph wheel lower support portion ι〇2ρ provided on the main plate 102. The chronograph wheel lower support portion 102p of the core 400 is the same as the scoring wheel lower support portion 102ρ using the core 100. Therefore, the chronograph system is rotatably arranged between the rear wheel bridge 108 and the main board 102, and the hour hand 4 5 9 (refer to a complete figure described later) is attached to the chronograph 4 5 8. The chronograph hour hand 45 9 constructs a chronograph indicating member. In the chronograph mode, the chronograph hand 4 5 9 is operated to indicate the elapsed time. Referring to FIG. 1, the rotation center of the chronograph wheel 4 5 8 is arranged above the main vertical axis 3 02 and at the center of the main board 3 00 and The main board 102 is located between 309 and 910. The main board 102 is located at "9 o'clock" on the center 100. The distance between the rotation center of the chronograph wheel 4 5 8 and the main board center 300 is the largest outer part of the 102. 1/2 of the radius. (2 · 4) 1/5 seconds indicating the structure of the wheel train. Next, the commentary is operated in a chronograph measurement mode according to the present invention. The 100's are rotatable for the wheels 45 8. Chronograph chronograph measurement: 5, 0 The reference shape of the board is 5 directions ". Approximately -50-(47) (47) 200405146 Needle-type electronic watch (pointer-type chronograph) The structure of the seconds indicating gear train. The 1/10 seconds indicating gear train includes: a motor for driving 1 /; [0 seconds indicating gear train and 1/5 seconds indicating gear train. Refer to FIGS. 9 and 10, 1 / 5 second motor includes: 1/5 second coil.  442, 1/5 second stator 444 and 1/5 second rotor 446. The W5 second coil block 442 and the 1/5 second rotor 446 used in the core 400 are the same as the time coil block 2 4 2 used in the above core 10 100, the time stator 2 4 4 and the time rotor 2 4 6 Of parts. The size and shape of the stator 4 4 4 used for the 1/4 second of the core 4 0 0 are the same as the size and shape of the time stator 244 used for the side of the core 1 100 above, except for controlling the time rotor (a ) 246 outside the shape of the rotating recess. When the 1/5 second motor drive signal output by IC (Integrated Circuit) 1 1 6 is input to the 1/5 second coil block 4 4 2, the 1/5 second stator 4 4 4 is magnetized to rotate for 1/5 second. Rotor 4 4 6. 1/5 seconds Rotor 4 4 6 series architecture to rotate for example, 1 80 degrees every 1/5 seconds. The 1/5 second rotor 446 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a rotor magnet. The upper shaft part of the rotor of 1/5 second 4 4 6 can be rotatably integrated with the bearing part 1 6 a of the rotor of 1/5 second provided on the wheel bridge (A) 106. The rotor upper supporting portion 1 06 a used for the 1/4 second of the core 4 0 0 is the same as the time supporting the upper supporting portion 106 a of the rotor (A) at the same time as the above-mentioned core 1 100. The lower shaft portion of the 1/5 second rotor 446 is rotatably integrated with the 1/5 second rotor lower support portion 102a provided on the main plate 102. The 1/5 second rotor lower support portion 102a used in the core 400 is the same as the time rotor (A) lower support portion 102a used in the above-mentioned core i 00. Therefore, the 1/6 second rotor 44 6 series is rotatably arranged between the wheel train bridge (A) 106 and the main board 102. -51-236 (48) (48) 200 405 146 1/5 CG intermediate wheel (A) 470 series architecture to rotate based on 1/5 second rotation of rotor 446. The 1 / 5CG intermediate wheel (A) 470 includes an upper shaft portion, a lower shaft portion, a pinion portion, and a wheel portion. The wheel structure of the 1/5 CG intermediate wheel (A) 470 meshes with the small teeth of the 1/5 second rotor 4 4 6. The upper shaft of the 1/5 CG intermediate wheel (A) 470 is rotatably integrated with the upper bearing portion 106fc of the 1 / 5CG intermediate wheel (A) provided in the wheel bridge (a) 106 (refer to the rear wheel described) Figure of bridge). The lower shaft portion of the 1 / 5CG intermediate wheel (A) 470 can be integrated into the lower supporting portion 102fc of the 1 / 5CG intermediate wheel (A) provided on the main plate 102 (refer to the drawing of the main plate described later). Therefore, the 1 / 5CG intermediate wheel (A) 470 series is rotatably disposed between the wheel bridge (A) 〖06 and the main board 1 〇2. The 1 / 5CG wheel 476 is based on the rotation of the 1 / 5CG intermediate wheel (B) 472 based on the rotation of the 1/5 C G intermediate wheel (A) 470. The 1/5 CG intermediate wheel (B) 472 includes: an upper shaft portion, a lower shaft portion, and a wheel portion. The wheel structure of the 1 / SCG intermediate wheel (B) 472 meshes with the small teeth of the 1 / 5CG intermediate wheel (A) 470. The upper shaft of the 1/5 CG intermediate wheel (B) 4 7 2 is rotatably integrated with the upper bearing portion 1 0CG of the 1 / 5CG intermediate wheel (B) provided in the wheel bridge (A) 106 (see below). Diagram of gear train bridging). The lower shaft portion of the 1/5 CG intermediate wheel (B) 4 72 is rotatably integrated with the lower support portion 102gC of the 1 / 5CG intermediate wheel (B) provided on the main plate 102 (refer to the drawing of the main plate described later). Therefore, the W5CG intermediate wheel (B) 472 series is rotatably arranged between the wheel train bridge (A) 106 and the main board 102. The 1 / 5CG wheel 476 includes an upper shaft portion 476a, an abacus bead portion 4 7 6 b provided at a lower shaft portion thereof, an intermediate shaft portion 4 7 6 c, and a wheel portion 4 7 6 d. 1/5 C G wheel 4 7 6 -52- (49) (49) 200405146 The wheel portion 221d system structure meshes with the pinion portion 220c of the 1/5 CG intermediate wheel (B) 472. The upper shaft portion 476a of the 1 / 5CG wheel 476 is rotatably integrated with the upper shaft portion 106c of the 1 / 5CG wheel provided at the wheel bridge (A) 106. 1/5 C used for the center of the center 400 is the same as the upper shaft part 10 6 c of the G wheel, as is used for the side of the center 100 for the second wheel / pinion upper shaft 106 c. The abacus bead 476b of the 1 / 5CG wheel 476 is rotatably disposed inside the center hole of the hollow shaft pinion 424b for the center. The center of rotation of the 1/5 C G wheel 4 7 6 is the center of the motherboard 3 0 0. The 1/5 CG wheel 476 series structure rotates by 1/5 second order. The 1/5 second chronograph hand 4 75 is attached to the 1/5 CG wheel 476. The 1/5 second chronograph hand 475 is a 1/5 second chronograph indicator (1/5 CG pointer). In the core 400, the second wheel / pinion holding spring 2 31 used for the side of the core 100 is not used. As a modified example, by changing the specifications of the IC, the stepping motor and the wheel train, instead of rotating the 1 / 5CG wheel that rotates one step every 1/5 seconds 47 6. The 1 second CG wheel that rotates one step every 1 second or every 1 A 1 / 2CG wheel that rotates one step per / 2 seconds or a 1 / 4CG wheel that rotates one step per second can be provided. (2 · 5) Refer to FIG. 4 for the architecture of the main board. The lower support part 102k of the scoring wheel is arranged above the main board reference horizontal axis 3 04 in the main board 102 and is located at the center of the main board 3 00 and the outer section 3 06 of the main board 102. Meanwhile, the main board 102 is arranged in the “6 o'clock direction” of the bezel 100. The 1/5 second rotor lower support part 102a, the 1 / 5CG intermediate wheel (A) lower support part 102fc, and the 1 / 5CG intermediate wheel (B) lower support part 102gc are arranged in the third area of the main board 102 3 3 0 . -53- 238 (50) (50) 200 405 146 Chrono / minute rotor lower support section 102f, Chrono / minute fifth wheel / pinion gear lower support section 102g, scoring intermediate wheel (a) lower support 102h, scoring middle wheel (b) lower support part 102j, chronograph middle wheel (A) bottom support part 102m, and chronograph middle wheel (B) bottom support part 102η are arranged on the main board 1 The third zone 330 in 〇2. The bottom support part 102 of the chronograph wheel is arranged in the main board 102 above the main board reference vertical axis 3 02 and between the main board center 300 and the main board 102's outer section 3 09. The main board 102 is arranged in the table. The center is 100, at 9 o'clock. "The lower support part 102r of the time rotor (B), the second support part 102s of the fifth wheel / pinion (B), and the fourth wheel / pinion i for the center 〇2dc, the lower support part 102t of the middle small seconds (A), and the lower support part 102u of the middle small seconds (B) are arranged in the fourth area 340 in the main board 102. The lower support part 102v of the small seconds is arranged in The position of the main board 102 above the main board reference horizontal axis 3 04 is between the main board center 300 and the outer section 3 12 of the main board 102. The main board 102 is arranged at the center of the center 100, at 12 o'clock, The guide pin 170p is arranged in the first zone 310. The guide pin 172p is arranged in the fourth zone 3 4 0. With the structure in this way, the main board 102 used for the epicenter 4 00 can be made the same as used in the watch The main board 1 02 of the heart 100. That is, the main board can use the table core 400 and the table core 100. (2. 6) Gear train bridge architecture (2. 6) Gear train bridging (A) and gear train bridging (B) -54- (51) (51) 200405146 Referring to FIG. 5, 1/5 second rotor upper support portion 106a, 1/5 CG intermediate wheel ( A) The upper support portion 106fc and the 1 / 5CG intermediate wheel (B). The upper support portion 106gc is a main plate center 300 disposed in the wheel train bridge (A) 106. The chronograph / minute rotor upper support section 107 f and the chronograph / minute fifth wheel / pinion upper support section 107g are arranged in the third zone 3 30 of the wheel train bridge (B) 107. Scoreboard intermediate wheel (A) upper support portion 106h, scoreboard intermediate wheel (B) upper support portion 106j, chronograph intermediate wheel (A) upper support portion 106m and chronograph intermediate wheel (B) The upper support portion 106n is arranged in the third region 330 in the train bridge (A) 106. Time rotor (B) upper support portion 106r, time fifth wheel / pinion (B) upper support portion 102s, fourth wheel / pinion upper support portion 102cc, and third wheel / pinion upper support portion l 〇2dc is arranged in the fourth zone 340 in the train bridge (A) 106. With the structure in this way, the wheel train bridge (A) 106 and the wheel bridge (B) 107 used for the epicenter 400 can be respectively the same as the wheel train bridge for the epicenter 100 ( A) 106 and train bridge (B) 10 7. (2. 7) Refer to FIG. 6 for the architecture of the rear wheel train bridge. Referring to FIG. Between the external parts of 108, the rear wheel train bridge is arranged at the 6 o'clock direction 55 of the center of the center 100. The support part 108 of the middle wheel (A) of the scoring machine, scores Chronograph intermediate wheel (B) upper support 1 0 j, chronograph intermediate wheel (a) upper support 1 008-55- 248 (52) 200405146 and chronograph intermediate wheel (B) upper support 1 〇8 η is arranged in the third zone 330 of the rear wheel 108. The support part 1 on the chronograph wheel is arranged at a position where the rear wheel train bridges above the reference vertical axis 3 of the motherboard and is located at the center rear wheel of the motherboard. Between the external parts of the bridge 108, the rear wheel bridges the "9 o'clock direction" of the center 108 of the 108. The upper support part 108 of the middle small seconds wheel (A) and the upper support part of the middle small seconds Korea The 108x1 series is located on the rear wheel train bridge 3 40 ° on the middle small seconds wheel upper support part 108. The v series is located above the main board reference horizontal axis 3 0 4 in the rear wheel train bridge and Between the main board and the outer part of the rear wheel bridge 108, the rear wheel bridge bridges the "12 o'clock direction" of the 108 epicenter 100. With this structure, it is used for the epicenter The rear wheel 1 08 of 4 0 0 can be made the same as the rear wheel 1 0 8 used for the above-mentioned center 100. That is, the rear wheel bridge can be used for the center 4 0 0.  100 ° (2 · 8) Arrangement of components in the table core Next, the preferred configuration of the components in the table core 400 will be explained with reference to FIG. 1, the rotation center of the reposition lever 1 4 0 ′ 1 4 0 C system second zone 3 2 0. The gear train positioning lever 440 is arranged in the first zone 310 and the fourth zone. The position where the relocation lever 140 'contacts the gear train positioning lever 440 is matched with a zone 3 1 0. Used to locate the middle small seconds wheel (B) 4 3 4 The wheel train bridge 1 0 8 3 00 and placed on the table η (B) The fourth zone is connected to the 108 center 3 00. At 3400, the positioning lever -56- (53) (53) 200405146 440 is a fourth zone 340 arranged on the rear side of the epicenter 400. A repositioning lever 1440 'for performing a repositioning operation is a second region 320 disposed on the surface side of the epicenter 400. With the structure in this manner, the wheel train positioning lever 440 firmly set to rotate the wheel train for operating the small second hand can be efficiently disposed on the surface side of the epicenter 400. The coil block center 442c of the 1/5 second coil block 442 can be arranged in the third zone 3 3 0. The center of rotation of the rotor 4 4 6 of the 1/5 second, the center of rotation of the 1/5 CG intermediate wheel (A) 4 7 0 and The center of rotation of the 1 / 5CG intermediate wheel (B) 4M can be arranged in the third zone 3 3 0. The rotation center of the minute wheel 226 may be arranged in the second zone 320 °. The coil block center 462c of the hour / minute coil block 462 may be arranged in the third zone 3 3 0. Rotation center of chronograph hour / minute rotor 466, rotation center of chronograph hour / minute fifth wheel / pinion 4 50, rotation center of scoring intermediate wheel (C) 4 51, rotation center of scoring instrument ( D) The rotation center of 45 3, the rotation center of the chronograph intermediate wheel (A) 452, and the rotation center of the chronograph intermediate wheel (B) 457 may be arranged in the third zone 3 3 0. The coil block center 4 6 2 c of the hour / minute coil block 4 62 may be arranged on the outside of the coil block center 442 c of the 1/5 second coil block 442 in the third zone 3 3 0. The rotation center of the chronograph hour / minute rotor 466 is arranged on the outside of the rotation center of the 1/5 second rotor 446 in the third zone 3 3 0. The rotation center of the scoring wheel 4 5 4 is arranged above the reference horizontal axis 3 04 of the main board and between the main board center 3 0 0 and the outer part 3 0 6 of the main board 102, and the main board 1 2 is arranged at the center 4 0 0 in the "6 o'clock direction". The distance between the center of rotation of the scoring wheel 4 5 4 and the center 300 of the main board is preferably mainly -57 · (54) (54) 200405146 30% to 70% of the radius of the largest outline portion of the plate 102, more preferably The radius of the largest external shape of the main board 102 is 45 ° /. To 55%, and is particularly preferably 1/2 of the radius of the largest outer shape of the main board 102. In addition, the rotation center of the chronograph wheel 45 8 is disposed above the main board reference vertical axis 3 02 and between the main board center 3 00 and the outer portion 3 09 of the main board 102, and the main board 102 is disposed at the center 4 0 0 The "9 o'clock direction". The distance between the rotation center of the chronograph wheel 45 8 and the center of the main board 300 is preferably 30% to 70% of the radius of the largest external shape of the main board 102, and more preferably 45% of the radius of the largest external part of the main board 102. % To 55%, and is particularly preferably 1/2 of the radius of the largest outer shape portion of the main board 102. The coil block center 4 8 2 of the center time coil block 4 8 2 can be arranged in the fourth zone 3 4 0. Center of rotation of time rotor (B) 4 8 6; center of rotation of time fifth wheel / pinion (B) 420; center of rotation of middle small second wheel (A) 432; center of small middle second wheel (B) 4 3 4 The rotation center, the rotation center of the center fourth wheel / pinion 421 and the rotation center of the center third wheel pinion 422 may be disposed in the fourth zone 3 40. With the structure in this manner, the plurality of coil blocks and the plurality of gear trains can be efficiently disposed on the surface side of the core 400. Here, the number of components of the frame train is not limited to the above number, and one or more transmission wheels may be additionally added. The rotation center of the small second wheel 43 6 is arranged above the reference horizontal axis 3 04 of the main board and between the main board center 3 00 and the outline part 3 1 2 of the main board 102. The main board 1 2 is arranged at the center 4 0 0. "1 2 o'clock direction". The distance between the rotation center of the small second wheel 43 6 and the center of the main board 300 is preferably 30% to 70% of the radius of the largest outline portion of the main board 102, and more preferably -58- (55) (55) 200405146 The radius of the largest outer portion of the board 102 is 45 to 55 percent, and is particularly preferably 1/2 of the radius of the largest outer portion of the main board 102. Preferably, the distance between the rotation center of all scoring wheels 4 5 4 and the center of the main board 300, the distance between the rotation center of the chronograph wheel 4 5 8 and the center of the main board 300, and the rotation of the small second wheel 4 3 6 The distance between the center and the center of the motherboard is 300 degrees. (2. 9) Operation of the second embodiment Next, the operation of the second embodiment of the pointer electronic timepiece (pointer timepiece) according to the present invention will be explained. Referring to FIG. 13, a complete combination 5 0 of an analog chronograph is provided with a housing 2 02. The housing 2 0 2 used in the second embodiment of the analog chronograph according to the present invention may be the same as the housing 202 of the analog chronograph used in the first embodiment of the present invention, or may be different therefrom. . The core 400 and the dial 104 are housed in a case 202. The dial 104 of the second embodiment of the analog chronograph used in the present invention may be the same as the dial 104 of the analog chronograph used in the first embodiment of the present invention described above, or may be different therefrom. The crown 204 is provided on the housing 202 and rotates integrally with the pointer positioning lever 110. The time of the center chronograph can be set by pulling out the crown 204 to the first stage and rotating the crown 204. That is, when the crown 204 is pulled out to the first stage, the small second hand 43.8 can be stopped, and the hour hand 230 and the minute hand 232 can be rotated by rotating the crown 204. The housing 202 is provided with a start / stop button 2 06 for starting and stopping the chronograph operation of the center chronograph. When the start / stop button is pressed 206 -59- " ι Λ A.  (56) 200405146 hour 'The signal related to the start operation and stop operation of the chronograph is transmitted to the IC 116 by replacing the spring. The housing 202 is provided with a reset button 208 for resetting the chronograph operation of the timepiece. When reset is pressed, the signal related to the reset operation of the chronograph is input to I C 1 1 6 by operation switching. Here, an operation indicating the current time will be explained. Reference, 1 3, The time of the center chronograph is set by pulling the crown 20 04 to and rotating the crown 204 to set the current time, and the crown 204 stage. In the phase, the rotor (B) 486 based on the time rotor (B) 4 8 6 is rotated and the time fifth wheel / pinion (B) is rotated. The small seconds wheel 4 3 6 is rotated through the middle small seconds wheel (A) 4 3 2 and the wheel (B) 4 3 4 based on the rotation of the fifth wheel / pinion (B). The small seconds wheel 4 3 6 rotates once per minute, so the small seconds hand 4 3 8 of the small seconds wheel 43 6 represents the "second" of the current time. Furthermore, the 5 center wheel / pinion 4 2 4 is rotated by the rotation of the fifth wheel / pinion (B) 420 between the middle wheel / pinion 421 and the center third pinion 422. The center J pinion 424 rotates one revolution per hour, so the center hollow pinion 424b attached to the center wheel / pinion 424 indicates the "minute" of the current time. The rotation of the hour wheel 22 8 through the minute wheel 226 rotates based on the rotation of the core wheel / pinion. The hour wheel 22 8 rotates the old circle, so the hour hand 234 attached to the hour wheel 22 8 indicates “hour”. It is transmitted by operating the center-cut button 208 spring. "Figure 9 to the first stage is pushed to the first turn, the time 420 is rotated by the middle small seconds 420, and the fourth turn is attached to the heart. Use the center pin 232 to center the middle E 12 Xiaoer current time -60- Λ Γ (57) (57) 200405146 Next, the time measurement operation will be explained. Refer to Figure 13 and stop resetting the time measurement In the phase, all the chronograph hands 4 5 9, the minute chronograph hands 45 5 and the 1/5 second seconds chronograph hands 4 7 5 are arranged at the "zero position (starting position)". That is, during the reset phase, All chronograph hands 45 9. The chronograph hands 4 5 5 and 1/5 second chronograph hands 4 75 are arranged at the position indicating “zero”. Refer to Figures 9 to 13 for the chronograph measurement mode by pressing the start / stop button 2 0 6 and start timing measurement. In the chronograph measurement mode, the chronograph hour / minute rotor 466 is rotated, and the chronograph hour / minute fifth wheel / pinion gear 45 0 is rotated based on the rotation of the chronograph hour / minute / second rotor 4 6 6. In addition, the scoring intermediate wheel (C) 4 51 and the chronograph intermediate wheel (A) 4 5 2 are rotated based on the rotation of the chronograph / second fifth wheel / pinion 25 0. The scoring wheel 454 is rotated based on the rotation of the scoring intermediate wheel (D) 45 3 based on the rotation of the scoring intermediate wheel (C) 4 5 1. In the chronograph measurement mode, the scoring pin 4 5 5 attached to the scoring wheel 454 indicates the "minute" of the elapsed time. In addition, the chronograph wheel 4 5 8 is rotated based on the rotation of the chronograph intermediate wheel (A) 452 via the rotation of the chronograph intermediate wheel (B) 4 5 7. In the chronograph measurement mode, the chronograph hand 4 5 9 attached to the chronograph wheel 45 8 indicates the "hour" of the elapsed time. Furthermore, in the chronograph measurement mode, the 1/5 second rotor 446 is rotated, and the 1/5 CG intermediate wheel (A) 470 is rotated based on the 1/5 second rotation of the rotor 446. The 1/5 C G wheel 4 7 6 is rotated based on the rotation of the 1/5 C G intermediate wheel (B) 4 7 2. In the chronograph measurement mode, the 1/5 second chronograph 47 5 series attached to the 1/5 CG wheel 476

24S -61-(58) (58) 200405146 The "second" of the elapsed time is expressed in 1/5 second units. Furthermore, in the chronograph measurement mode, when the start / stop button 206 is pressed, At the next time, the chronograph measurement can be stopped. In the phase of stopping the chronograph, the chronograph hour hand 459 stops at the "hour" phase indicating the elapsed time, and the minute chronograph hand 455 stops at the "minute" indicating the elapsed time. In addition, the 1/5 second chronograph hand 4 75 stops at the "second" phase indicating the elapsed time in "1/5 second units". During the phase where the measurement is stopped, the reset button 208 When pressed, all the chronograph hands 4 5 9, the minute chronograph hands 4 5 5 and 1/5 second chronograph hands 4 7 5 return to the position indicating "zero" (refer to Figure 8). (3) Other embodiments Next, other embodiments of the present invention will be explained. In the following, the differences between the other embodiments of the present invention and the first embodiment of the present invention will be mainly explained. Therefore, the parts other than the following are related to the present invention. The above description of the first embodiment and the above description about the second embodiment of the present invention will be applied Thereon. (3.  1) The structure of the core of the side chronograph is in the above-mentioned core 100 of the side chronograph, although the components of the structure of the core 100 are preferably configured to constitute the relative vertical axis 3 02 In the structure shown in FIG. 1, the components of the structure epicenter can be configured to constitute a structure commensurate with the structure shown in FIG. 1 with respect to the reference vertical axis 302 of the motherboard. That is, referring to FIG. 14, in the epicenter 100, the coil block center 242c of the time coil block 242 -62- (59) (59) 200405146 is disposed in the third zone 3 3 0. The rotation center of the time rotor (A) 246 and the rotation center of the time fifth wheel / pinion (A) 220 are arranged in the third zone 3 3 0. The center of rotation of the side third wheel / pinion 222 is arranged in the fourth zone 3 4 0. The rotation center of the minute wheel 226 is arranged in the second area 320. The coil block center 262c of the hour / minute / second coil block 262 is arranged in the third zone 3 3 0. Rotation center of minute wheel 226, chronograph minute / second fifth wheel / pinion 2 50 0 rotation center, chronograph intermediate wheel (A) 2 5 1 rotation center, scoring intermediate wheel (A) 252 The rotation center, the rotation center of the chronograph intermediate wheel (B) 253 and the rotation center of the chronograph intermediate wheel (B) 25 7 are arranged in the third zone 3 3 0. The coil block center 2 6 2 c of the hour / minute / second coil block 2 6 2 is arranged outside the coil block center 242c of the time coil block 2 4 2 in the third zone 3 30. The rotation center of the hour / minute / second rotor 266 is arranged on the outside of the rotation center of the time rotor (A) 246 in the third zone 3 3 0. The rotation center of the chronograph wheel 2 5 4 is arranged above the reference horizontal axis 3 04 of the main board and between the main board center 3 00 and the outline part 3 0 6 of the main board 102. The main board 1 0 2 is arranged at the center 10 0 0 "6 o'clock direction". Furthermore, the center of rotation of the scoring wheel 2 5 8 is arranged above the main board reference vertical axis 3 02 and between the main board center 3 00 and the main board 102's outer shape 3 09. The main board 102 is arranged at the center 100. " At 9 o'clock. " The center of the coil block 2S2c of the coil block 282 of 1/10 second is arranged in the fourth zone 3 4 0. The center of rotation of the rotor 2 8 6 1/1 10 seconds, the fifth wheel / pinion 2 7 0 Rotation center, rotation center of 1/10 stopwatch middle wheel (A) 2 7 1 -63- (60) (60) 200405146 rotation center and rotation center of 1/10 stopwatch middle wheel (B) 272 In the fourth zone 340. The center of rotation of the 1/1/10 second wheel 2 7 4 is located above the reference horizontal axis 3 04 of the motherboard and between the motherboard center 3 00 and the external part 3 1 2 of the motherboard 102, and the motherboard 10 02 is arranged at the center 1 00's "12 o'clock direction". The distance between the rotation center of the chronograph wheel 2 5 4 and the center of the main board 3 0 0, the distance between the rotation center of the scoring wheel 2 and the center of the main board 3 0 0 and the rotation center of the chronograph wheel 274 and A distance of 3 00 from the center of the main board constitutes a first class. In contrast, referring to FIG. 15, a structure may be formed in the core 100D so that the rotation center of the time rotor (A) 246 and the rotation center of the fifth wheel / pinion (A) 2 2 0 are arranged at the first The rotation center of the third zone / pinion 2 2 2 in the fourth zone is 3 3 0, and the rotation center of the second wheel 2 2 6 is located in the first zone 3 1 0. Rotation center of minute / second rotor 2 6 6, chronograph minute / second fifth wheel / pinion 2 50 0 rotation center, chronograph intermediate wheel (A) 2 5 1 rotation center, chronograph intermediate wheel ( B) The rotation center of 2 5 3 and the scoring intermediate wheel (B) The rotation center of 2 5 7 is arranged in the fourth zone 3 4 0, and the rotation center of the 1 2/10 second rotor 2 8 6, 1 / 10 seconds rotation center of the fifth wheel / pinion 2 70, 1/10 rotation center of the chronograph (A) 2 71 rotation center and 1/1/10 seconds of the counter wheel (b) 2 7 2 The center of rotation is located in the third zone 3 3 0. Furthermore, in the center 100D, the rotation center of the chronograph wheel 2 54 is arranged above the reference horizontal axis 300 of the main board and between the main board center 300 and the outer section 312 of the main board 102d. The motherboard 〇2d is arranged in the "12 o'clock direction" of the epicenter-64- (61) (61) 200405146 100, and the rotation center of the scoring wheel 25 8 is arranged above the reference vertical axis 302 of the motherboard and on the motherboard. Between the center 300 and the main board 102d and 3 09, the main board 102d is arranged in the "9 o'clock direction" of the epicenter 100D, and the rotation center of the 1/10 countdown wheel 274 is arranged on the reference horizontal axis of the main board The position above 3 04 is between the center of the main board 3 00 and the outer shape portion 3 06 of the main board 102D. The main board 102D is arranged in the “6 o'clock direction” of the crown 100. (3. 2) The structure of the center of the center chronograph is in the above table core 4 0 0 of the center chronograph, although the components that structure the center of the center 4 0 0 are preferably configured to form a reference vertical axis 3 with respect to the motherboard 3 In the structure shown in FIG. 9 of 02, the components of the structure epicenter can be configured to constitute a structure commensurate with the structure shown in FIG. 9 with respect to the reference vertical axis of the motherboard. That is, referring to FIGS. 9 and 16, in the epicenter 400, the coil block center 442c of the 1/5 second coil block 442 is disposed in the third zone 3 3 0. The rotation center of the rotor 446 in 1/5 second, The center of rotation of the 1 / 5CG intermediate wheel (A) 470 and the center of rotation of the 1 / 5CG intermediate wheel (B) 472 are disposed in the third zone 330. The rotation center of the minute wheel 226 is disposed in the second zone 320. The coil block center 4 6 2 c of the hour / minute coil block 4 62 is arranged in the third zone 3 3 0. Center of rotation of the chronograph / minute rotor 4 6 6; Center of rotation of the chronograph / minute fifth wheel / pinion 4 50; Center of rotation of the scoring intermediate wheel (c) 4 5 1; Center of scoring The rotation center of the wheel (D) 45 3, the rotation center of the chronograph intermediate wheel (A) 4 5 2 and the square rotation center of the chronograph intermediate wheel (b) 4 5 7 are arranged in the second district 3 3 0. Hour / minute coil block 4 6 2 line • 65- (62) (62) 200 405 146 coil block center 462c is located outside the coil block center 442c of the coil block 442 in the 1/5 second of the third zone 3 3 0 on. The center of rotation of the chronograph hour / minute rotor 466 is arranged on the outside of the center of rotation of the rotor 446 in the 1/5 second in the third zone 3 3 0. The center of rotation of the scoring wheel 454 is located above the reference horizontal axis 3 0 4 of the main board and between the center 3 0 of the main board and the outer part 3 0 6 of the main board 1 0 2. The main board 1 0 2 is disposed at the center 4 0 0 in the "6 o'clock direction". In addition, the rotation center of the chronograph wheel 4 5 8 is arranged above the reference vertical axis 3 2 of the main board and between the main board center 3 0 0 and the outer portion 3 0 9 of the main board 1 0 2, and the main board 1 〇 2 is arranged at the center of the center 4 0 0 in the direction of 9 o'clock. The time coil block 4 8 2 of the center is arranged in the fourth zone. The rotation of the time rotor (B) 4 8 6 Center, rotation center of the fifth wheel / pinion (B) 4 2 0, rotation center of the middle small second wheel (A) 4 3 2, rotation center of the middle small second wheel (B) 4 3 4 The center of rotation of the four-wheel / pinion 421 and the center of rotation of the third wheel pinion 422 are arranged in the fourth zone 3 4 0. The center of rotation of the small second wheel 4 3 6 is arranged on the reference horizontal axis of the motherboard 3 0 4 The upper position is between the main board center 300 and the main board 1 0 2 outline section 3 12. The main board 1 102 is arranged in the “12 o'clock direction” of the center 400. All the scoring wheels 4 5 4 The distance between the center of rotation and the center of the main board 300, the distance between the center of rotation of the chronograph wheel 4 300 and the center of the main board 300, and the center of rotation of the small second wheel 4 3 6 and The distance from the center of the plate to the distance of 3 00 constitutes a first class. -66- (63) (63) 200405146 In contrast, referring to Fig. 17, in the epicenter 400D, it is possible to form a framework 'to make 1/5 seconds of the rotor 4 4 The center of rotation of 6, the center of rotation of 1/5 CG intermediate wheel (A) 4 7 0 and the center of rotation of / 5 c G intermediate wheel (B) 4 7 2 are located in the second zone 3 2 0, and the sub-wheel 2 The rotation center of 2 6 is arranged in the first zone 3 1 0, the rotation center of the chronograph rotor 4 6 6, the rotation center of the chronograph / minute fifth wheel / pinion 45 0, and the scoring intermediate wheel. (C) 451 rotation center, scoring intermediate wheel (D) 4 5 3 rotation center, chronograph intermediate wheel (A) 45 2 rotation center and chronograph intermediate wheel (b) 45 7 rotation center It is arranged in the second zone 3 2 0, the rotation center of the time rotor (B) 4 8 6 and the rotation center of the time fifth wheel / pinion (B) 4 2 0, the middle small second wheel (A) 4 3 2 The center of rotation, the center of rotation of the middle small seconds wheel (b) 4 3 4, the center of rotation of the center fourth wheel / pinion 42 1 and the center of rotation of the center third wheel pinion 4 2 2 are arranged in the third zone. 3 3 0. At In the center 400D, the rotation center of the scoring wheel 454 is arranged above the main board reference horizontal axis 304 and between the main board center 300 and the main board 102D's outline 312. The main board 102D is arranged at the center 400 of the "1" 2 o'clock direction ", the rotation center of the chronograph wheel 45 8 is arranged above the main board reference vertical axis 3 02 and between the main board center 3 00 and the main board 1 〇 2 D 3 0 9 and the main board 1 0 2 D is arranged in the "9 o'clock direction" of the center 4 0 0 D, and the rotation center of the small second wheel 43 6 is arranged above the reference horizontal axis 3 04 of the main board and at the center of the main board 3 00 and the shape of the main board 102D. Department 3 between 06. The main board 102D is arranged in the "6 o'clock direction" 'of the table core 400D. -67 ^ (64) (64) 200405146 (4) The structure of the wheel train positioning lever (4. 1) Gear train positioning lever of the first type Next, the gear train positioning lever of the first type will be explained in detail in the second embodiment of the pointer electronic watch according to the present invention. Referring to Figs. 9 and 18, as described above, the "front side" of the center 400 of the analog electronic watch is provided with a center time wheel train, a switching device, and the like. The center time gear train includes a center time motor and a center gear train. The center uses the time wheel system structure to rotate by the rotation of the center time motor. The hour hand 23 0 represents the "hour" of the current time, the minute hand 232 represents the "minute" of the current time, and the small second wheel 4 3 4 represents the "second" of the current time. Time Rotor (B) 4 8 6 series architecture to rotate, for example, 180 degrees per second. The time fifth wheel / pinion (B) 420 system is configured to rotate based on the rotation of the time rotor (B) 4 8 6. The center uses the fourth wheel / pinion 4 2 1 and the middle small seconds wheel (A) 4 3 2 system to rotate based on the rotation of the fifth wheel / pinion (B) 4 2 0. The center sun gear / pinion 4 2 4 frame is configured to rotate via the rotation of the center third wheel pinion 422 based on the rotation of the center fourth wheel / pinion 421. The center uses a sun gear / pinion 42 4 system to make one rotation per hour. The minute hand 232 is attached to the center hollow pinion 424b for the center sun gear / pinion 424. The hour wheel 228 is configured to rotate via the rotation of the minute wheel 2 2 6 based on the rotation of the center sun wheel / pinion 4 2 4. Time Wheel 228 Series. The structure comes to rotate once every 12 hours. The middle small seconds wheel (A) 432 system is structured to rotate based on the rotation of the fifth wheel / pinion (B) 4 2 0. The small seconds wheel 4 3 6 series architecture rotates through the middle -68- (65) (65) 200405146 The small seconds wheel (B) 4 3 4 rotates based on the rotation of the middle small seconds wheel (A) 4 3 2. The small seconds hand 4 3 8 is attached to the small seconds wheel 4 3 6. Small seconds hand 4 3 8 frame seconds indicator. The rotation center of the small seconds wheel 4 3 6 is arranged above the reference horizontal axis 3 0 4 of the main board and between the main board center 3 0 0 and the outer part 3 12 of the main board 4 2. The main board 402 is arranged at the center of the 400 "At 12 o'clock." The distance between the rotation center of the small seconds wheel 4 3 6 and 0 3 0 is about 1/2 of the radius of the largest outer shape of the main plate 4 2. Referring to FIGS. 18 and 21, the repositioning lever 1450 includes a relocation conductive spring 140d for performing a reset operation, and a gear train repositioning lever holding part 1 4 2 for retaining the gear train positioning lever 440 and An operating spring 143 for operating the gear train positioning lever 4 4 0. The positioning lever 134 is provided with an operating pin 1 3 4p of an operating hole 1 4 Oh inserted into the repositioning lever 140 '. When the pointer positioning lever 1 10 is pulled out from the zero stage to the first stage by rotating the positioning lever 1 3 4, the yoke 1 3 6 is thus rotated by the structure. Furthermore, when the pointer positioning lever 1 10 is pulled out from the zero stage to the first stage by rotating the positioning lever 1 3 4, the repositioning lever 14 0 ′ is rotated by the structure. In the stage of pulling the pointer positioning lever 110 to the first stage, the analog electronic watch can be reset by conducting the repositioning conductive spring 140d of the repositioning lever 140 ′ to the repositioning pattern of the circuit block. Furthermore, when the pointer positioning lever 110 is pulled out from the zero stage to the first stage, the gear train positioning lever 440 is configured to move linearly by rotating the positioning lever 134 and the reset lever 1 40 :. The gear train positioning lever 4 4 0 is used to set the middle small seconds wheel (B) 43 4. The rotation of the hand positioning lever 1 1 0 to the first stage. The gear train positioning lever 440 includes: a guide window portion 44 Of and (66) (66) 200405146 440g, an operation window portion 440h, and a rotating gear train positioning portion 440k for positioning the middle small seconds wheel (B) 434. The guide window portion 440f of the gear train positioning lever 440 is guided by the guide pin 170p of the main board 102. The guide window portion 440g of the wheel train positioning lever 440 is guided by a guide pin 172p of the main board 102. Therefore, the gear train positioning lever 440 is integrated to the main board 102 so as to move linearly with respect to the main board 102. According to the architecture shown in FIG. 18, the gear train positioning rod 440 is configured without overlapping the components with hands attached, that is, the hour wheel 228, the center sun wheel / pinion 424, the small second wheel 436, and 1/5 CG Round 476. According to this structure, the gear train positioning lever 440 is configured without overlapping the components with the hands attached, and therefore, the thickness of the electronic watch can be reduced. When the pointer positioning lever is pulled out to the first stage, the repositioning lever 1 40 'is rotated and the rotation operation spring 143, the wheel train positioning lever 440 can be along the surface of the main board 102 guided by the guide pins 170p and 172P. Move linearly. When the gear train positioning lever 4 4 0 linearly moves, the positioning portion 440k of the gear train positioning lever 4 4 0 is brought into contact with the wheel portion 434d of the middle small second wheel (B) 43 4, whereby the middle small second The rotation of wheel (B) 434 can be set. According to this structure, because the gear train positioning rod 44 0 moves linearly, the positioning portion 4 4 0 k of the gear train positioning rod 4 4 0 is brought to a position smaller than the middle by operating from the direction of the vertical wheel portion 4 3 4 d. The wheel part 43 4d of the second wheel (B) 43 4 is in contact. Therefore, when the middle small seconds wheel (B) 434 is set, there is very little concern for rotating the middle small seconds wheel (b) 43 4 by the wheel train positioning lever 440. The center of rotation of the repositioning lever 14 ° is arranged in the second zone 3 2 (\. The parts where the wheel train positioning lever 4 4 0 and the relocation lever 140 ′ are in contact with each other and the guide pin 17oop are arranged in the first zone. 3 1〇. The positioning part 440k of the wheel train positioning lever 440 and the middle small seconds wheel (b) > 70- (67) (67) 200405146 434 are in contact with the wheel part 43 4d and the guide pin 172p is arranged at the first District 4 3 40 〇 (4. 2) Gear train positioning lever of the second type Next, the gear train positioning lever of the second type will be explained in detail in the second embodiment of the pointer electronic watch according to the present invention. The points of the second type wheel train positioning lever according to the second embodiment of the present invention and the first type wheel train positioning lever according to the second embodiment of the present invention will be mainly explained below. Therefore, the above explanation regarding the first type of gear train positioning lever according to the second embodiment of the present invention will be applied to portions other than the following. Referring to FIG. 22, as described above, the center of the analog electronic timepiece 500 is provided with a center time wheel train, a switching device, and the like on the surface side. The small seconds hand 4 3 8 series is attached to the small seconds wheel. 4 3 6. The rotation center of the small seconds wheel 4 3 6 is arranged on the main board reference horizontal axis 3 (M position and between the main board center 300 and 312 of the main board 502, and the main board 5 02 is arranged on the center 500 "12 o'clock direction". The distance between the center of rotation of the small seconds wheel 4 3 6 and the center of the main board 3 0 0 is about 1/2 of the radius of the largest shape of the main board 5 0 2. The reposition lever 5 3 0 includes : Reposition conductive spring 53 0d for performing reset operation, wheel train repositioning lever holding part 5 3 2 for holding gear train positioning lever 54 0, and operation spring 5 for operating wheel train positioning lever 5 4 0 3 3. When the pointer positioning lever 1 1 0 is pulled out to the first stage by rotating the positioning lever 1 3 4, the repositioning lever 5 3 0 is also rotated. Then, pull the pointer positioning lever 丨 〖〇 to the first Phase by stage, the analog electronic watch can be repositioned to the circuit block by repositioning the conductive spring 5 3 0 d to the circuit block. And reset. -71-(68) (68) 200405146 Furthermore, when the pointer positioning lever 1 1 0 series is pulled out to the first stage, the wheel positioning lever 5 4 0 series structure is used to rotate the positioning lever 1 3 4 and the repositioning lever 5 3 0 and move linearly. The gear train positioning mechanism 5 4 0 system causes the setting of the rotation of the middle small seconds wheel (B) 434 to pull the pointer positioning lever 1 1 0 to the first stage The gear train positioning lever 540 includes a guide window portion 54 Of and 540g, an operating window portion 5 40h, and a gear train positioning portion 5 40k for positioning the rotation of the middle small seconds wheel (B) 434. The gear train positioning lever The guide window portion 5 40f of 5 4 0 is guided by the guide pin 510p of the main board 502. The guide window portion 540g of the wheel train positioning lever 540 is guided by the guide pin 512p of the main board 502. Therefore, the wheel train The positioning bar 5 40 is integrated into the main board 5 0 2 so as to move linearly relative to the main board 5 02. According to the architecture shown in FIG. 22, the gear train positioning bar 5 4 0 is configured such that a part thereof overlaps the small second wheel. 4 3 6. According to this architecture, the gear train positioning lever system is configured to overlap the small seconds wheel 4 3 6, so the size of the electronic watch can be reduced. When the pointer lever is pulled At the first stage, the repositioning lever 5 3 0 was turned by Fang 'and was operated by rotating the Bomb 5 3 3. The gear train positioning lever 5 4 0 could be along the surface of the main board 502 guided by the guide pins 510p and 512p. Moving linearly. When the gear train positioning lever 5 4 0 moves linearly, the positioning part 5 4 0 k of the gear train positioning lever 5 4 0 is brought to the wheel part 4 with the middle small seconds wheel (b) 4 3 4 3 4 d Touch 'Take' the middle small seconds wheel (B). The rotation of 3 4 can be set. The rotation center of the repositioning lever 5 3 0 is arranged in the second zone 3 2 0. The parts of the wheel train positioning lever 540 and the reposition lever 53o which are in contact with each other: the parts and the guide pins 5iop are arranged in the first zone 3 1 0. Positioning part 5 4 Ok of the gear train positioning lever 5 4 0 and the part 4 3 4 d in contact with the wheel part 4 3 4 d of the middle small second wheel (B) 4 3 4 and the guide pin 5〗 2 p series • 72- (69) (69) 200,405,146 is located in the fourth zone 3 40. (4. 3) Third type wheel train positioning lever Next, the third type wheel train positioning lever will be explained in detail in the second embodiment of the pointer electronic watch of the present invention. The points of the third type wheel train positioning lever according to the second embodiment of the present invention and the first type wheel train positioning lever according to the second embodiment of the present invention will be mainly explained below. Therefore, the above explanation regarding the first type of wheel train positioning lever according to the second embodiment of the present invention will be applied to portions other than the following. Referring to Fig. 23, as described above, the "surface side" of the center 600 of the analog electronic timepiece is provided with a center time train, a switching device, and the like. The small seconds hand 4 3 8 is attached to the small seconds wheel 4 3 6. The rotation center of the small seconds wheel 4 3 6 is arranged above the reference horizontal axis 3 04 of the main board and between the main board center 3 00 and the main board 312 of the main board 6 02. The main board 602 is arranged at the “core 2” of the center 600. ". The distance between the rotation center of the small second wheel 4 3 6 and the center of the main board 300 is about 1/2 of the radius of the largest outer shape of the main board 602. The reposition lever 63 0 includes a reposition conductive spring 63 0 d for performing a reset operation, a wheel train reposition lever holding portion 632 for holding the wheel train positioning lever 640, and an operation for operating the wheel train positioning lever 640. Spring 63 3. When the pointer positioning lever 110 is pulled out to the first stage by rotating the positioning lever 134, the repositioning lever 630 is also rotated. At the stage where the pointer positioning rod 110 is pulled out to the first stage, the analog electronic watch can be reset by conducting the repositioning of the positioning rod 63 0 and transmitting the missile Zan 63 0d to the repositioning pattern of the circuit block. Furthermore, when the pointer positioning lever 1 1 0 series is pulled out to the first stage, the gear train positioning lever 640 series structure rotates the positioning lever 134 and the repositioning lever -73- (70) (70) 200405146 6 3 〇 and move linearly. The gear train positioning mechanism 6 4 0 is used to cause the setting of the small seconds wheel 4 36 to rotate the pointer positioning lever 丨 〖0 to the first stage. The wheel train positioning lever 640 includes a guide window portion 640f and 640g, an operation window portion 640h, and a wheel train positioning portion 6 40k for positioning the rotation of the small seconds wheel 4 3 6. The guide window portion 640f of the gear train positioning lever MO is guided by a guide pin 610p of the main plate 602. The guide window portion 640g of the gear train positioning lever 640 is guided by a guide pin 612p of the main plate 602. Therefore, the gear train positioning lever 640 is integrated to the main board 602 so as to move linearly with respect to the main board 602. According to the structure shown in Fig. 23, the gear train positioning rod 604 is arranged so that a part of it overlaps the small seconds wheel 4 36. According to this structure, the wheel train positioning lever system is configured to overlap the small seconds wheel 4 3 6, and therefore, the size of the electronic watch can be reduced. When the pointer positioning lever is pulled out to the first stage, the repositioning lever 63 0 is rotated and the spring 63 3 is rotated, and the gear train positioning lever 640 can be moved along the main board 602 guided by the guide pins 61 Op and 61 2p. The surface moves linearly. When the gear train positioning lever 640 moves linearly, the positioning part 64 0k of the gear train positioning lever 640 is brought into contact with the wheel part 43 6d of the small seconds wheel 43 6, whereby the rotation of the small seconds wheel 436 can be set . The rotation center of the repositioning lever 63 0 is arranged in the second zone 3 20. The parts of the gear train positioning lever 640 and the repositioning lever 630 and the guide pins 61 Op which are in contact with each other are arranged in the first area 310. A portion where the positioning portion 640k of the gear train positioning lever 640 contacts the wheel portion 436d of the small seconds wheel 436 and the guide pin 612p are arranged in the fourth zone 340. (4. 4) Fourth type gear train positioning lever Next, in the second embodiment of the pointer electronic watch of the present invention, the fourth type gear train positioning lever will be explained in detail in -74-(71) (71) 200405146. The points of the fourth type wheel train positioning lever according to the first embodiment of the present invention and the first type wheel train positioning lever according to the second embodiment of the present invention will be mainly explained below. Therefore, the above explanation regarding the first type of wheel train positioning lever according to the second embodiment of the present invention will be applied to portions other than the following. Referring to FIG. 24, as described above, the center of the analog electronic watch 700, on the surface side, is provided with a center time wheel train, switching device and the like. The small seconds hand 4 3 8 series is attached to the small seconds Wheel 4 3 6. The rotation center of the small seconds wheel 4 3 6 is arranged above the reference horizontal axis 3 0 4 of the main board and between the main board center 300 and the outer portion 312 of the main board 702. The main board 7 2 is arranged at "12 o'clock direction" of the center 700. The distance between the rotation center of the small second wheel 4 3 6 and the center of the main board 300 is about 1/2 of the radius of the largest shape of the main board 7 0 2. The positioning lever 7 3 0 includes a reset positioning conductive spring 7 3 0 d for performing a reset operation, a wheel train repositioning lever holding part 7 3 2 for holding the wheel train positioning lever 74, and a operation for positioning the wheel train. The operating spring 7 3 3 of the lever 7 4 〇. When the pointer positioning lever 1 10 is pulled out to the first stage, the repositioning lever 7 3 0 is also rotated by rotating the positioning lever 1 3 4. 10 〇Pull out to the first stage 'analog electronic watch can reposition the conductive spring 7 3 0d to the circuit block through the conductive repositioning rod 7 3 0 Reposition the pattern and reset. Furthermore, the 'wheel train positioning lever 740 series mechanism moves linearly by rotating the positioning lever 134 and the reposition lever 7 3 0. The wheel train positioning lever 740 system causes the setting of the small second wheel 43. The rotation of the dagger is at the stage of pulling the pointer positioning lever 110 to the first stage. The gear train positioning lever 740 includes: a guide window portion 74 Of and 7 40 g, an operation window portion 7 4 〇h, and a small positioning rod. Second wheel 4 3 6 Rotating wheel 2S0 -75- (72) (72) 200405146 System positioning part 74 0k. The guide window part 74 of the wheel system positioning lever 740 is made by the guide pin 71 Op of the main board 7 02. Guided. The guide window 74g of the gear train positioning lever 74 is guided by the guide pin 71 2p of the main board 702. Therefore, the gear train positioning lever 740 is integrated into the main board 702 so as to be 702 relative to the main board. It moves linearly. According to the architecture shown in FIG. 24, the gear train positioning lever 74 is configured without overlapping the components with the pointer attached, that is, the hour wheel 2 2 8, the center sun wheel / pinion 4 2 4, Small seconds wheel 4 3 6 and 1/5 CG wheel 4 7 6. According to this architecture, the wheel train positioning rod system is configured to not overlap the parts with the pointer attached, so the electronic watch's The thickness can be reduced. When the pointer positioning lever is pulled out to the first stage, the repositioning lever 7 3 0 is rotated, and the rotation operation spring 7 3 3, and the gear train positioning lever 7 4 0 can be guided by the guide pin. The surfaces of the main board 702 guided by 7 1 〇p and 7 1 2p move linearly. When the gear train positioning lever 7 4 0 moves linearly, the positioning part 7 4 0 k of the gear train positioning lever 7 4 0 is brought to By contacting the wheel portion 4 3 6 d of the small seconds wheel 4 3 6, the rotation of the small seconds wheel 4 3 6 can be set. The rotation center of the repositioning lever 7 3 0 is arranged in the second zone 3 2 0. The parts of the wheel train positioning lever 7 40 and the reposition lever 7 300 that are in contact with each other and the guide pin 7 10 are arranged in the first zone 3 10. The positioning portion 740k of the gear train positioning lever 7 4 0 in contact with the wheel portion 43 6d of the small seconds wheel 43 6 and the guide pin 7i2p are arranged in the fourth zone 340. The above-mentioned structures of the first to fourth types of reposition levers and gear train positioning levers can be applied to an analog chronograph with a small second hand, or to an analog electronic watch with a small second hand without a chronograph . (4 · 5) Other embodiments of the wheel train positioning lever-76- (73) 200405146 Although the above-mentioned implementation of the pointer electronic watch according to the present invention implements the structures of the first to fourth type relocation levers and the wheel train positioning lever, The rotation center of the second wheel 43 6 is located at the position of the reference horizontal axis of the main board and is between the main board center 3 00 and the outer part 312 of the main board “12 1” arranged at the center of the main board. When the main board is positioned above the reference horizontal axis 3 0 4 and between the center 3 00 and the outer side of the main board arranged in the "6 o'clock direction" of the table core, the components of the table core can be configured to frame relative to the vertical axis 3 02 is in mirror image with the structure shown in Figures 22 to 24. That is, 'the rotation center of the small second wheel 4 3 6 is arranged above the main flat axis 3 0 4 and is located at the center of the main board 3 00 and equipped with it' "6 o'clock direction" between the outer shape of the main board 306, in the description of the fourth type of repositioning lever and gear train positioning lever, "the first can be read as" the second zone 320 ", The second area is 32 °, which can be read as 3 3 0 ", the third area 3 3 0" can be read as, and the fourth area is 34 0 "and ,, fourth] is read as "third zone 3 3 0". According to the present invention, in a pointer electronic watch provided with a small second hand having a rotation center at a position other than the watch, a small and thin finger watch having a mechanism capable of positioning a gear train for rotating the small second hand can be realized . Furthermore, according to the present invention, in the case of an electronic watch capable of arranging the chronograph second hand at the heart and also arranging the chronograph second hand at the center of the center of the watch ', for the example of arranging the small second hand at the center of the center of the watch, related Note the rotation of the clock above the direction of the small 3 04 ”is in the middle part of the main board 306 The main board reference commensurate knot plate reference water is placed in the center of the first to-zone 3 1 0," "the third zone 1 3 40 ,, The center of the center is solid enough to be positioned outside the center of the needle-type electronic watch center -77- 262 (74) (74) 200405146. It has a mechanism capable of firmly positioning the wheel train for rotating the small second hand. Small and thin analog electronic watches can be implemented. [Brief Description of the Drawings] The preferred form of the present invention is illustrated in the accompanying drawings, in which: FIG. 1 shows an embodiment of an analog electronic watch according to the present invention, the shape of the center of the chronograph watch viewed from the surface side A plan view, (in FIG. 1, the explanation of some components is omitted and the bridge members are shown by dashed lines); FIG. 2 is a side view showing a motor and a watch of a chronograph according to an embodiment of the analog electronic watch according to the present invention Fig. 3 is a partial cross-sectional view showing a battery of a chronograph for a side watch and a part of a train wheel of a watch core according to an embodiment of an analog electronic watch according to the present invention; 4 is a plan view showing an embodiment of the analog electronic watch according to the present invention when the shape of the main board is viewed from the surface side (in FIG. 4, the explanation of the shape of part of the main board is omitted); FIG. 5 is a diagram showing a record according to the present invention. An example of a timepiece is a plan view of the appearance of the wheel train bridge (A) and the wheel train bridge (B) viewed from the surface side. (In FIG. 5, part of the wheel train bridge (A) and the wheel train bridge (b) The explanation of the shape is omitted); Figure 6 shows The embodiment of the analog electronic watch according to the embodiment of the figure shows the shape of the rear wheel bridge (the side of the main board) from the rear side. (In FIG. 6, the illustration of the shape of the rear wheel bridge is omitted.) It is a block diagram of the embodiment of the analog electronic watch according to the present invention. -78- (75) (75) 200405146 The block diagram of the motor of the timepiece and the wheel train bridge of the movement; FIG. 8 shows a block diagram according to the present invention. Plan view of the complete outline of a chronograph for a side of an embodiment of an analog electronic timepiece; FIG. 9 shows the outline of the center of the chronograph for an embodiment of an analog electronic timepiece according to the present invention from a surface side observation center Plan view (in FIG. 9, some parts are omitted); FIG. 10 is a view showing a motor of a chronograph for a center of an embodiment of an analog electronic watch according to the present invention and a part of a wheel train of a watch core Sectional view; FIG. 11 is a partial cross-sectional view showing a part of a wheel and a battery of a chronograph for a central timepiece according to an embodiment of the analog electronic watch according to the present invention; FIG. 12 is a pointer according to the present invention The center of the embodiment of the electronic timepiece uses the motor and the core of the timepiece according to § 2 Block diagram of the gear train; Figure 1 3 is a plan view showing the complete outline of a central chronograph according to an embodiment of the pointer electronic watch according to the present invention; Figure Ϊ 4 is a diagram showing the implementation of a pointer electronic watch according to the present invention The side view of the example is a plan view of the outline configuration of the motor of the chronograph and the wheel train of the watch core (some parts are omitted in Fig. 14); Fig. 15 shows another analog electronic watch according to the present invention. A plan view of the outline configuration of the motor of the chronograph and the wheel core of the embodiment side (in FIG. 15, some parts are omitted); FIG. 16 is a diagram showing an analog electronic watch according to the present invention. A plan view of the outline configuration of the motor of the chronograph and the wheel of the center of the embodiment (in FIG. 16, some parts are omitted); FIG. 17 is a view showing another example of the analog electronic watch according to the present invention. First implementation -79- (76) (76) 200405146 The plan view of the outline configuration of the motor of the chronograph for the center and the gear train of the core (in Fig. 17, some parts are omitted); · Fig. 1 8 The side display of an embodiment of an analog electronic timepiece according to the present invention The plan view of the outline configuration of the first type wheel train positioning rod and the time indicating wheel train in the heart (some parts are omitted in FIG. 18); FIG. 19 shows an embodiment of the analog electronic watch according to the present invention. Partial cross-sectional view of the outline structure of the first type wheel train positioning lever, pointer positioning lever and repositioning lever in the center of the side chronograph; FIG. 20 shows an embodiment of an analog electronic watch according to the present invention. Partial cross-sectional view of the outline structure of the first type wheel train positioning lever, reposition lever and middle small seconds wheel (B) in the center of the side chronograph; Figure 21 shows an analog electronic watch according to the present invention The side of the embodiment uses a positioning lever, a sub-wheel, a re-positioning lever and a 1/5 CG intermediate wheel (B) in the center of the chronograph; a partial cross-sectional view of the outline structure; The embodiment of the analog electronic watch is a plan view of the configuration of the second type wheel train positioning rod and the time indicating wheel train in the center of the chronograph (in FIG. 22, some parts are omitted); An embodiment of an analog electronic watch according to the present invention is shown The third type of train wheels and the lever positioning a time indication wheel train configuration plan shape of the heart of a chronograph Table (in FIG. 23, part of the components are omitted); and FIG. 2 4 is a plan view showing the configuration of the fourth type of reposition lever and time indicating gear train in the center of a side chronograph according to an embodiment of the analog electronic watch according to the present invention (in FIG. Parts are omitted). -80- (77) 200405146 Comparison table of main components 1 06e Upper support part of the wheel 1 02e Lower support part of the wheel 100 Table core 1 00D Core 102 Main plate 102a Time rotor (A) Lower support section 102b Time fifth wheel / small Gear (A) lower support 1 02d side third wheel / pinion lower support 1 02f hour / minute rotor lower support 102g hour / minute fifth wheel / pinion lower support 1 02h Chronograph intermediate wheel (A) lower support part 102j Chronograph intermediate wheel (B) lower support part 102k Chronograph wheel lower support part 10 2m Scoring instrument intermediate wheel (A) bottom support part 1 02n Scoring device Lower support of intermediate wheel (B) 1 02p Lower support of scoring wheel 1 02r 1/10 seconds Rotor lower support 102s 1/1 0 seconds Fifth wheel / pinion lower support 1 02t 1/1 0 seconds Bottom support of the middle wheel (A) 1 0 2 u 1/1 Bottom support of the chronograph middle wheel (B) 102v 1 / 10v Bottom support of the chronograph wheel 102a Bottom support of the time rotor (B) 1 02dc Center third wheel / pinion lower support -81-(78) 200405146 1 02t Middle small second wheel (A) lower support 1 02υ Middle small second wheel (B) lower support 1 02v Small second wheel lower support 1 02f Hour / minute rotor lower support 102g Hour / minute fifth wheel / pinion lower support 1 02h Scorer intermediate wheel (C) lower support l 〇2j Lower support of scoring wheel (D) 102k Lower support of scoring wheel 10 2m Lower support of chronograph wheel (A) 1 02n Lower support of chronograph wheel (B) 1 02p Bottom support part 1 02fc 1/5 CG intermediate wheel (A) Upper support part 1 02gc 1 / 5CG Intermediate wheel (B) Lower support part 1 02D Main board 1 03 Central tube 104 Dial 1 06 Gear train bridge (A) 106a Time rotor (A) upper support 1 06b Time fifth wheel / pinion (A) upper support 106c Side second wheel / pinion upper shaft 1 06d Side third wheel / pinion upper support 1 06r . 1/10 second upper support part of rotor 10 6s 1/10 second 5th wheel / pinion upper support part 106a time rotor (B) upper support part -82- (79) 200405146 1 0 6 cc center fourth wheel / Pinion upper support 1 06dc Third wheel for center / Pinion upper support 1 06fc 1 / 5CG Intermediate wheel (A) Upper support 1 0 6 gc 1 / 5CG Intermediate wheel (B) Upper support 107 Gear train bridge (B) 1 07f hours, minutes / seconds, rotor's upper support 107 g, hours, minutes / second fifth. Wheel / pinion upper support 1 07f Hour / minute Rotor upper support 107g Hour / minute 5th. Wheel / pinion upper support part 1 08 Rear wheel bridge 1 08h Chronograph intermediate wheel (A) Upper support part 108j Chronograph intermediate wheel (B) Upper support part 108k Chronograph wheel upper support part 1 0 8 m Scoreboard intermediate wheel (A) Upper support 1 08n Scoreboard intermediate wheel (B) Upper support 1 08p Scoreboard upper support 1 08t 1/10 Stopwatch intermediate wheel (A) Upper support 1 08u 1/10 chronograph intermediate wheel (B) upper support 1 08 v 1/10 chronograph wheel support i section 1 08CH center hole 1 08t middle small seconds wheel (A) upper support 1 08u middle small seconds wheel (B) On. Support 1 08 v Small second wheel upper support 1 0 8h Scorer intermediate wheel (C) Upper support > 83- (80) 200405146 108j Scorer intermediate wheel (D) Upper support 108k Scoring wheel Support 108m Chronograph intermediate wheel (A) Upper support part 1 08n Chronograph intermediate wheel (B) Upper support part 1 08p Chronograph wheel upper support part 110 Pointer positioning rod 114 Crystal unit 116 Integrated circuit 120 Battery 122 Switch spring 128 Negative battery end 13 Locating wheel 1 3 Op Rotating center shaft 132 Clutch wheel 1 34 Positioning rod 1 34c Rotating center 1 34p Operating pin 136 Yoke 136c Rotating center 140 Relocating rod 1 40d Repositioning conductive spring 1 40f Gear train Positioning part 140c Rotation center 1 4 (T Reposition lever-84-269 200405146 140c (81) Rotation center 1 40h Operation hole 142 Wheel train relocation lever holding part 143 Operating spring 1 70p, 1 72p Guide pin 200 Complete combination 202 outer Case 204 crown 206 start / stop button 208 reset button 220 time fifth wheel / pinion (A) 220a upper shaft portion 220b lower shaft portion 2 2 0 c pinion 220d Wheel part 22 1 Second wheel / pinion gear on the side 22 1a Upper shaft part 22 1b Abacus bead part 22 1c Pinion part 222 Third wheel / pinion gear on the side 222c Pinion part 222d Wheel part 224 Side wheel on the side / Pinion gear 224a Center wheel for side -85- (82) Hollow shaft pinion for side wheel pinion upper shaft part Lower shaft part pinion part wheel part hour wheel hour wheel part hour hand side second pinion / pinion holding spring minute hand Second hand time coil block center time time stator time rotor (A) upper shaft part lower shaft part pinion part rotor magnet chronograph minutes / second fifth wheel to small gear chronograph intermediate wheel (A) scoring intermediate wheel (A ) Counter intermediate wheel (B) -86- (83) 200405146 254 Counter wheel 255 seconds chronograph 25 7 Counter intermediate wheel (B) 25 8 scoring wheel 259 minutes chronograph 262 Hour / minute coil Block 262c Coil block center 264 hours and minutes / seconds stator 266 hours and minutes / seconds rotor 270 1/10 seconds fifth wheel / pinion 27 0a upper shaft portion 2 7 0b lower shaft portion 2 7 0c upper pinion portion 27 0d Wheel part 270f Lower pinion part 27 1 W1 〇 Chronograph intermediate wheel (A) 27 1a Shaft section 27 1b Lower shaft section 27 1 d Wheel section 272 1/1 0 Chronograph intermediate wheel (B) 272a Upper shaft section 27 2b Lower shaft section 272d Wheel section 274 1/0 0 Second wheel-87- (84 200405146 2 7 4a Upper shaft part 2 7 4b Lower shaft part 274d Wheel part 27 5 1/10 second chronograph 282 1/10 second coil block 282c coil block center 284 1/10 second stator 286 1/10 second rotor 286a on Shaft portion 286b Lower shaft portion 286c Pinion portion 2 8 6d Rotor magnet 300 Main plate center 302 Main plate reference vertical axis 303 Outer portion 304 Main plate reference horizontal axis 306 Outer portion 309 Outer portion 3 10 First 1¾ 3 12 Outer portion 320 Second zone 330 Second 340 Fourth 400 Center-88- (85) 200405146 400D Center 402 Main board 420 Time fifth wheel / pinion 420a Upper shaft portion 420b Lower shaft portion 420c Upper pinion portion 420d Wheel portion 420f Lower pinion portion 42 1 Fourth wheel / pinion for center 42 1 a Upper shaft part 42 1 b Lower shaft part 42 1 c Pinion part 42 1 d Wheel part 422 Third wheel pinion for center 422a Upper shaft portion 422b Lower shaft portion 422c Pinion portion 422d Wheel portion 424 Center wheel / pinion 424a Center wheel 424b Center hollow pinion 432 Center small seconds wheel 432a Shaft section 43 2b Lower shaft section -89- 274 (86) 200405146 43 2d Wheel section 434 Small second hand 434 Middle small seconds wheel (B) 43 4a Upper shaft section 43 4b Lower shaft section 43 4d Wheel section 436 Small seconds wheel 4 3 6a Upper shaft part 43 6b Lower shaft part 43 6d Wheel part 43 8 Small second hand 440 Gear train positioning lever 440f, 440g Guide window part 440h Operation window part 440k Gear train positioning part 442 1/5 second coil block 442c Coil block center 444 1 / 5 seconds stator 446 1/5 seconds rotor 450 chronograph hour / minute fifth wheel / pinion 45 1 scoring intermediate wheel (C) 452 chronograph intermediate wheel (A) 453 scoring intermediate wheel (D) 454 scoring wheel -90- (87) 200405146 455 chronograph hand 457 chronograph intermediate wheel (B) 45 8 chronograph wheel 459 chronograph 462 chronograph / minute coil block 462c coil block center 464 chronograph Hour / minute stator 466 Hour / minute rotor 470 1 / 5CG intermediate wheel ( A) 472 1 / 5CG intermediate wheel (B) 475 1/5 second chronograph 476 1 / 5CG wheel 476a upper shaft 476b abacus bead 476c middle shaft 476d wheel 482 center time coil block 4 82c coil block center 484 Center time stator 486 Time rotor (B) 500 Complete combination 500 Table core 502 Main board 5 1 Op, 512p guide pin -91 (88) 30405146 530 Relocation lever 5 3 0d Relocation conductive spring 532 Gear train relocation lever holding part r ο ο 3 JJ Operating spring 540 Gear train positioning lever 540f > 5 40g Guide window part 5 40h Operating window part 5 40k Wheel train positioning part 600 Epicenter 602 Main plate 6 1 0 p, 6 1 2 p Guide pin 63 0 Heavy Positioning lever 63 Od Repositioning conductive spring 632 Gear train repositioning lever holder 63 3 Operating spring 640 Gear train lever 640f, 640g Window guide 640h Operation window 640k Gear train positioning part 7 00 Core 702 Main board 7 1 Op , 7 1 2p guide pin 73 0 reposition lever 73 Od reposition -92 spring guide (89) 00405146732 train wheels relocation lever operating spring holder fixing portion 733 'train jumper 740 740. f, 74 Og Guide window 740h Operation window 740k Wheel alignment -93-

Claims (1)

200405146 Π) Pick up and apply for patent scope 1 · A pointer electronic watch, including: ~ motherboard, base plate that constructs the core; ~ bridging members to support: components that structure the core; ~ time information indicator wheel The main board center of the main board rotates as a rotation center to indicate time information; ~ Small second wheel rotates at a position other than the center of the table core as a rotation center; a pointer positioning lever for correcting the time information indication A switching device to switch the position of the pointer positioning lever; a dial to indicate the time information; a repositioning lever when the pointer positioning lever is pulled out from the zero stage to the first stage; Rotating by operating the switching device; and ~ gear train positioning lever, when the pointer gear lever is pulled out from the zero stage to the first stage, 'the gear train positioning lever structure moves linearly based on the rotation of the repositioning lever Wherein, the gear train positioning rod structure causes rotation of the small second wheel or other wheels used to rotate the small second wheel. 2 · As for the analog electronic watch in item 1 of the scope of patent application, in which the gear train positioning rod system is configured without overlapping the parts attached to the hands, that is, the time information means the non-wheel and small seconds wheel. 3. The analog electronic watch according to item 1 of the patent application range, wherein the gear train positioning rod system is arranged to overlap the small seconds wheel. Wherein 4. If the pointer electronic watch of item 1 of the scope of patent application, * 94-(2) 200405146 The reposition lever includes a relocation to perform a reset operation to hold the gear train relocation lever holding portion of the gear train relocation lever. The operating spring of the gear train relocation lever. 5 · If the pointer type of the patent application scope item 1 passes through the center of the motherboard and is parallel to the vertical axis of the central axis of the pointer positioning rod and passes through the center of the motherboard and perpendicular to the motherboard reference horizontal axis, the motherboard is defined on the motherboard; where the The motherboard is provided with a first area, which is arranged on one side of the motherboard and is close to the finger on the motherboard reference horizontal axis, and the motherboard is provided with a second area, which is arranged on the motherboard's reference side and close to the motherboard's reference horizontal axis. The main board is provided with a third zone, which is arranged on the other side where the second vertical axis is present and on the side of the main board with reference to the horizontal pin positioning lever, and the main board is provided with a fourth zone, which The main board of the first zone is on the side of the other side of the vertical axis, the horizontal axis is far from the side of the pointer positioning rod; wherein the rotation center of the small second wheel is arranged above the main line, the first zone, and the fourth The position between the center above the boundary of the section and the outer shape of the main board; wherein the rotation center of the repositioning lever is arranged in the first position of the wheel train positioning lever and part of the system The first region; and wherein the positioning portion of the positioning bar gear train is disposed in the fourth region and brought into line contact portion. Pass the missile treasure, use, and use to operate the sub-table, where the main board of the pass line refers to the reference vertical axis, the reference vertical axis, the side of the vertical positioning pin, the side of the vertical axis, and the side of the other axis of the vertical axis. Where there is the reference horizontal axis of the main board and the second zone of the main board; the wheel to be positioned of the relocation lever -95- 280 (3) (3) 200405146 6. As the first item in the scope of patent application A pointer-type electronic watch, wherein the wheel train positioning rod includes a window guide portion, the main board includes two guide pins for guiding the wheel train positioning rod, and the window guide portions of the wheel train positioning rod are separately structured to Guided by a guide pin of the main board, the wheel train positioning rod system is integrated to the main board to cause linear movement relative to the main board, and one of the guide pins is disposed in the first zone and the other It is located in the fourth area. 7. A pointer-type chronograph, including: a main board, a base plate that constructs the core; a bridging member to support the components that form the core; a time information indicator wheel, using the main board center of the main board as the rotation center While rotating to indicate the time information; a pointer positioning lever to correct the time information indication;-a switching device to switch the position of the pointer positioning lever; a dial to indicate the time information; wherein the motherboard includes By using the watch core to construct the supporting part of the rotor and gear train of the "central chronograph" and by using the watch core to construct the rotor and gear train supporting side " The bridge member includes: using the table core to construct the center, the center using a chronograph, the rotor and the wheel support portion, and the use of the table core to construct the "side, The rotor of the chronograph and the supporting part of the gear train; the rotor and gear train integration used to construct the "central chronograph" is used to cause the support of the main board and the bridge member relative to -96- (4) (4) 200405146 where the time information is a time indicating member that rotates by using the center of the motherboard as the center of rotation, and the position between the center of the motherboard and the outline of the motherboard Another time indicating member that rotates as the center of rotation is shown; the measurement result of one of the times is by the time indicating member that rotates as the center of rotation, and between the center of the main board and the outer shape of the main board The position of the position is indicated as another timing indicator member rotated by the rotation center; the repositioning lever can be rotated by operating the switching device when the pointer positioning lever is pulled out from the zero stage to the first stage; and when the pointer When the positioning lever is pulled out from the zero stage to the first stage, a wheel train positioning lever moves linearly based on the rotation of the repositioning lever; wherein the wheel train positioning lever mechanism causes the rotation of the positioning wheel to be used to rotate another time Indicates the gear train of the component. 8 · The analog electronic watch according to item 7 of the scope of patent application, wherein the main board passing through the center of the main board refers to a vertical axis and parallel to the center axis of the pointer positioning rod; and the main board reference passing through the center of the main board and perpendicular to the main board refers to a vertical axis The horizontal axis is defined on the main board; wherein the main board is provided with a first zone, which is arranged on one side of the main board with reference to the vertical axis and on the side of the main board reference horizontal axis that is close to the pointer positioning rod, the main board is provided with a second zone , Which is arranged on the other side of the main board reference vertical axis and on the side of the main board reference horizontal axis which is close to the pointer positioning rod, the main board is provided with a third zone which is arranged on the main board reference vertical axis where the second zone exists On the other side of the motherboard and on the side of the motherboard reference horizontal axis far from the finger -97- (5) (5) 200405146 pin positioning lever, and the motherboard is provided with a fourth zone, which is configured in the presence of the first The main board of the zone is on the other side of the reference vertical axis and on the side of the main board reference horizontal axis away from the pointer positioning rod; wherein the other time indicating member's center of rotation is It is arranged above the reference horizontal axis of the main board, above the boundaries of the first zone and the fourth section, and at a position between the center of the main board and the main board and the outer part; wherein the rotation center of the relocation lever is arranged at the first Zone 2; the part of the wheel train positioning lever and the reposition lever brought into contact with each other are arranged in the first zone; and the positioning part of the wheel train positioning lever is brought in and will be positioned The parts in contact with the wheels are arranged in this fourth zone. 9 · The analog electronic watch according to item 7 of the patent application, wherein the wheel train positioning lever includes two guide windows, the main board includes two guide pins for guiding the wheel train positioning lever, and the wheel train positioning lever The guide windows are separately structured to be guided by the guide pins of the main board, the wheel train positioning rod system is integrated to the main board so as to cause linear movement relative to the main board, and one of the guide pins is arranged at The first zone and the other are located in the fourth zone. -98-