CH707742A2 - sprung balance system, part of clockwork and timepiece. - Google Patents

Abstract

The invention relates to a sprung balance system for reducing the error in an escapement and for easily adjusting the step, a timepiece movement that includes this balance and a timepiece that includes this movement of a workpiece. watchmaking. The sprung balance system includes a balance shaft (30) on which a balance wheel (20) is externally and fixedly mounted and a sprung spring for which an inner end (43) is connected to the balance shaft (30). The coil spring is formed such that its inner peripheral surface (40a) intersects a central axis O of the rocker shaft (30) when the inner peripheral surface (40a) of the coil spring (40) is extended into a axial direction of the balance shaft (30).

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

The present invention relates to a pendulum, a timepiece movement including the pendulum and a timepiece.

2. Description of the prior art

[0002] A mechanical timepiece includes an exhaust / speed regulating mechanism for controlling the rotation of a cylinder, a center mobile, a third mobile and a second mobile, all forming a finishing gear. The exhaust / speed regulating mechanism is generally formed to have an escape wheel, an anchor and a pendulum. The balance is formed to have a balance wheel, a balance shaft which serves as a center of rotation of the balance, a spiral spring which is formed in a spiral shape to follow the Archimedes curve and which causes the balance to rotate reciprocally to a predetermined oscillation cycle using expansion and contraction, and a collar that secures the coil spring to the balance shaft. Fluctuations in the oscillation cycle of the pendulum influence the precision of the timepiece. Therefore, it is important to set the oscillation cycle to a predetermined control value.

[0003] FIG. 23 is a graph illustrating the influence on the gait which is caused by an error in the escapement where the vertical axis represents the step (second / day) and the horizontal axis represents the oscillation angle (°) of the balance.

As error factor in the oscillation cycle of the balance, we know the error in the exhaust. Due to the error in the escapement, the gait fluctuates in response to the swing angle of the pendulum. More specifically, as illustrated in FIG. 23, the oscillation angle of the balance decreases due to the decrease in the torques of the mainspring which is the energy source of the work train, and consequently the walking decreases. In particular, it is known that the step decreases significantly when the oscillation angle of the balance is 200 ° or smaller.

By casualness, U.S. Patent No. 7,648,265 (Patent Document 1) discloses a stud which supports the outer end of the spiral spring so as to be movable by sliding radially outwardly. In addition, the book "On Isochronous of the balance timepiece" written by Yasujiro Oshima, 1957, Journal (1) of the Horological Institute of Japan, pages 3 to 17 (non-patent document 1) discloses that it is possible to to change the characteristics of the step relative to the oscillation angle of the balance by slidingly displacing the outer end of the spiral spring radially outwards, which is arranged when the central axis of the archimedean curve and the central axis of the balance shaft are eccentric.

[0006] FIG. 24 is a graph illustrating the walking characteristics influenced by the eccentricity of the spiral spring and the sliding movement of the outer end where the vertical axis represents the walking (second / day) and the horizontal axis represents the oscillation angle (°) of the balance. In fig. 24, the solid line represents walking characteristics when the center of the hairspring is arranged to be eccentric in the direction of the outer end and the outer end of the hairspring is fixed at a predetermined position. The dashed line represents the characteristics of walking when the center of the hairspring is arranged to be eccentric in the direction of the outer end and the outer end of the hairspring is fixed after having shifted radically towards the end. outside from the predetermined position by a predetermined distance. The two-dot line represents walking characteristics when the center of the hairspring is arranged to be eccentric in the direction of the outer end and the outer end of the hairspring is fixed after radially sliding inwardly from the predetermined position by the predetermined distance.

As illustrated in FIG. 24, it is possible to adjust the step so that it increases in a range of the oscillation angle of approximately 220 ° or smaller, so that the center of the spiral spring is arranged to be eccentric in the direction of the outer end and the outer end of the spiral spring is moved radially outwardly.

FIG. 25 is a graph illustrating the adjustment of the step where the vertical axis represents the step (second / day) and the horizontal axis represents the oscillation angle (°) of the balance. In fig. 25, the line represents the characteristics of walking after adjustment. The dashed line represents the characteristics of walking when the center of the hairspring is arranged to be eccentric in the direction of the outer end and the outer end of the hairspring is fixed after sliding radially towards the outer end. outside from the predetermined position by the predetermined distance. The two-dot line represents the characteristics of walking before adjustment (equivalent to the walking characteristics in Fig. 23).

As illustrated in FIG. 25, it is possible to improve the gait in the range of the oscillation angle of approximately 220 ° or smaller, in such a way that the center of the spiral spring is arranged to be eccentric in the direction of the outer end and that the outer end of the spiral spring is moved radially outwardly from the predetermined position by the predetermined distance. Therefore, it is possible to suppress the decrease in walking that is caused by the decrease of the swing angle of the balance. In particular, in the range of oscillation angle of the beam of approximately 200 ° or smaller, in which the step decreases significantly due to the influence of the error in the exhaust, it is possible to suppress effectively reducing the gait that is influenced by the error in the exhaust. Therefore, it is possible to obtain stabilized walking characteristics with little, fluctuating over a wide range of oscillation angles (in Fig. 25, 150 ° to 300 °).

As described above, according to the prior art, the spiral spring is arranged to be eccentric in the direction of the outer end relative to the central axis of the balance shaft and the outer end. spiral spring is fixed after sliding radially outwards. Alternatively, the outer end of the hairspring is arranged to be eccentric in the opposite direction and the outer end of the hairspring is fixed after being radially inwardly shifted. In this way, it is considered that it is possible to obtain stabilized walking characteristics over a wide range of oscillation angles of the beam by suppressing the decrease in walking that is influenced by the error in the exhaust.

However, in the prior art, it is necessary to arrange the central axis of the archimedean curve of the spiral spring and the central axis of the balance shaft so that they are eccentric. In addition, it is necessary to adjust the step by moving the outer end of the coil spring in response to the eccentric direction and eccentricity. However, since the central axis of the spiral spring is a virtual axial line, a dedicated measuring instrument is required to measure the eccentric direction and the eccentricity of the spiral spring. In addition, it is difficult to use a measurement method and a method of calculating the eccentric direction and the eccentricity in the spiral spring. Therefore, it is extremely complicated to adjust the step by moving the outer end in response to the eccentric direction and the eccentricity of the spiral spring as described in the prior art, thereby leaving room for improvement.

[0012] Therefore, the present invention aims to create a balance that is able to reduce the error in the exhaust by easily adjusting the step and is able to obtain stabilized walking characteristics, a movement of room watchmaking that includes the pendulum, and a timepiece that includes the timepiece movement.

SUMMARY OF THE INVENTION

To solve the problem described above, a rocker of the present invention includes a rocker shaft which is rotatably arranged with respect to a support member and to which a rocker wheel is mounted externally and fixedly; and a spiral spring which is formed to follow the Archimedean curve and in which its inner end is connected to the rocker shaft and its outer end is connected to the support member. When the inner peripheral surface of the coil spring is extended in the axial direction of the rocker shaft, at least a portion in the inner peripheral surface is formed to intersect the central axis of the rocker shaft.

With the present invention, when the inner peripheral surface of the coil spring is extended in the axial direction of the rocker shaft, at least the portion in the inner peripheral surface is formed to intersect the central axis of the coil. 'balance shaft. It is therefore possible to arrange at least the portion of the spiral spring so that it is inclined relative to the central axis of the balance shaft. Here, it is confirmed that the step can be increased in the range of the oscillation angle of the beam in which the step decreases significantly due to the influence of the error in the escapement, when at least the part of the spiral spring is arranged to be inclined relative to the central axis of the balance shaft. Therefore, it is possible to suppress the decrease in gait which is influenced by the error in the escapement by arranging at least the part of the spiral spring so that it is inclined with respect to the central axis of the pendulum tree. In addition, since the central axis of the spiral spring is the axial virtual line, it has been difficult to measure the eccentric direction and the eccentricity of the spiral spring in the prior art. On the other hand, since the inclination angle of the hairspring can be easily measured, it is possible to easily adjust the inclination angle of the hairspring. Therefore, thanks to the pendulum of the present invention, it is possible to reduce the error in the exhaust by easily adjusting the step, and it is possible to obtain the stabilized walking characteristics.

The inner end of the spiral spring is connected to the balance shaft by a collar which is mounted externally and fixed to the balance shaft. In at least one of the inner end of the hairspring, the rocker shaft and the collar, an inner end tilt arrangement structure is provided in which the inner end of the hairspring is provided with such that when the inner peripheral surface of the coil spring is extended in the axial direction, at least a portion in the inner peripheral surface crosses the central axis of the balance shaft.

With the present invention, since the internal end tilt arrangement structure, wherein the inner end of the coil spring is disposed such that at least a portion in the inner peripheral surface of the spiral spring crosses the central axis of the balance shaft, is disposed in at least one of the inner end of the spiral spring, the balance shaft and the collar, at least a portion of the spiral spring can be reliably arranged to be inclined with respect to the central axis of the balance shaft. Therefore, it is possible to reliably arrange at least the portion of the hairspring so that it is inclined relative to the central axis of the balance shaft. In this way, it is possible to suppress the decrease of the step which is influenced by the error in the escape. In addition, the inner end tilt arrangement structure is provided in at least one of the inner end of the coil spring, the balance shaft and the collar. Therefore, it is possible to easily adjust the inclination angle of the coil spring to have any desired angle of inclination by changing the shape of the element in which the tilting arrangement structure of the inner end is disposed.

In addition, the internal end tilt arrangement structure arranges the inner end of the spiral spring to intersect the central axis of the balance shaft when, in the inner peripheral surface of the spiral spring. the surface fixing the inner end which is to be fastened to the collar is extended in the axial direction.

With the present invention, in the inner peripheral surface of the spiral spring, it is possible to arrange the fastening surface of the inner end so that it is fixed to the collar so that it is inclined relative to the central axis of the balance shaft. Here, it is confirmed that the step can be increased in the range of the oscillation angle of the beam in which the step decreases significantly due to the influence of the error in the exhaust, by arranging the mounting surface the inner end of the spiral spring so that it is inclined relative to the central axis of the balance shaft. Therefore, it is possible to suppress the decrease in gait which is influenced by the error in the exhaust, by arranging the fastening surface of the inner end of the spiral spring so that it is inclined relative to the central axis of the balance shaft.

In addition, the outer end of the spiral spring is connected to the support element by a pin and a support pin which supports the pin. In at least one of the outer end of the hairspring, the peg and the peg support, an outer end tilt arrangement structure is provided in which the outer end of the hairspring is disposed of so that when the inner peripheral surface of the spiral spring is extended in the axial direction, at least a portion in the inner circumferential surface crosses the central axis of the balance shaft.

With the present invention, in at least one of the outer end of the spiral spring, the bolt and the bolt carrier, the external end tilt arrangement structure is arranged which arranges the outer end of the spiral spring such that at least the portion in the inner peripheral surface of the spiral spring crosses the central axis of the balance shaft. Therefore, it is possible to reliably arrange at least the portion of the hairspring so that it is inclined relative to the central axis of the balance shaft. In this way, it is possible to suppress the decrease of the step which is influenced by the error in the escape. In addition, in at least one of the outer end of the hairspring, the peg and the peg support, the outer end tilt arrangement structure is disposed. Therefore, it is possible to easily adjust the tilt angle of the coil spring to have any desired tilt angle by changing the shape of the element in which the tilt arrangement structure of outer end is arranged.

In addition, the outer end tilt arrangement structure is formed to have the peak. The stud is arranged to be rotatable about a radially axial line of the spiral spring relative to the stud mount and is arranged to be rotatable about a tangent to the Archimedean curve in the outer end of the spring. -spiral. The outer end of the spiral spring is supported by the stud when the stud is rotated at least around the radially axial line of the spiral spring or around the tangent of the outer end of the spiral spring.

With the present invention, the outer end tilt arrangement structure is formed to have the stud, is arranged to be rotatable about the radially axial line of the coil spring, and is arranged to be rotatable. around the tangent to the Archimedes curve in the outer end of the spiral spring (hereinafter referred to simply as "tangent"). Therefore, it is possible to tilt the outer end of the coil spring in any desired direction by turning the pin around the radially axial line of the coil spring and around the tangent of the outer end of the spring. -spiral. In particular, it is possible to arbitrarily adjust the inclination angle and tilt direction of the outer end of the coil spring in response to the tilt angle of the inner end when the inner end spiral spring is arranged so that it is inclined. In addition, when the stud rotates at least around the radially axial line of the spiral spring or around the tangent of the outer end of the spiral spring, the outer end of the spiral spring is supported by the stud. Therefore, in the inner peripheral surface of the spiral spring, it is possible to arrange the inner peripheral surface of the outer end so that it is fixed to the stud so as to be inclined with respect to the central axis of the coil. 'balance shaft.

Here, it is confirmed that the step can be increased in the range of the oscillation angle of the balance in which the step is decreased significantly due to the influence of the error in the exhaust, when the The outer end of the spiral spring is arranged to be inclined relative to the central axis of the balance shaft. In particular, it is confirmed that the step can be further increased when the inner end of the springspiral is arranged so that it is inclined relative to the central axis of the balance shaft and the outer end of the spiral spring is arranged to be inclined relative to the central axis of the balance shaft. Therefore, it is possible to effectively suppress the decrease in gait which is influenced by the error in the escapement by arranging the inner end of the spiral spring so that it is inclined with respect to the central axis of the coil. the balance shaft and arranging the outer end of the spiral spring so that it is inclined relative to the central axis of the balance shaft.

In addition, there is provided a timepiece movement of the present invention in which the beam described above is inserted.

In addition, there is provided a timepiece of the present invention which includes the timepiece movement described above.

With the present invention, it is possible to obtain a movement of a timepiece and a timepiece that are highly accurate and have few errors in the exhaust.

With the present invention, when the inner peripheral surface of the spiral spring is extended in the axial direction of the balance shaft, at least a portion in the inner peripheral surface crosses the central axis of the shaft of balance. Therefore, it is possible to arrange at least the portion of the spiral spring so that it is inclined relative to the central axis of the balance shaft. Here, it is confirmed that the step can be increased in the range of the swing angle of the balance in which the step is significantly decreased due to the influence of the error in the escapement, when at least the part the spring-spiral is arranged to be inclined relative to the central axis of the balance shaft. Therefore, it is possible to suppress the decrease in gait which is influenced by the error in the escapement by arranging at least the part of the spiral spring so that it is inclined with respect to the central axis of the pendulum tree. In addition, since the central axis of the coil spring is the virtual axial line, it has been difficult to measure the eccentric direction and eccentricity of the coil spring in the prior art. On the other hand, since the inclination angle of the hairspring can be easily measured, it is possible to easily adjust the inclination angle of the hairspring. Therefore, thanks to the balance of the present invention, it is possible to reduce the error in the exhaust by easily adjusting the step, and it is possible to obtain the stabilized characteristics of the step.

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] <tb> Fig. 1 <SEP> is an external view of a timepiece according to one embodiment. <tb> Fig. 2 <SEP> is a front view seen from the front side of a movement. <tb> Fig. 3 <SEP> is a front view of a beam according to a first embodiment. <tb> Fig. 4 <SEP> is a sectional view taken along the line A-A in FIG. 3. <tb> Fig. <SEP> is an enlarged view of a collar of FIG. 4. <tb> Fig. 6 <SEP> is an explanatory view of a piton and a piton support. <tb> Fig. 7 <SEP> is a graph illustrating the change in gait with respect to the swing angle of the balance. <tb> Fig. 8 <SEP> is a graph illustrating the change in gait with respect to the swing angle of the pendulum. <tb> Fig. 9 <SEP> is an explanatory view of a balance according to a first example of modification of the first embodiment. <tb> Fig. <SEP> is an explanatory view of a balance according to a second example of modification of the first embodiment. <tb> Fig. 11 <SEP> is an explanatory view of a balance according to a third example of modification of the first embodiment. <tb> Fig. 12 <SEP> is an enlarged view of an inner end of a spiral spring. <tb> Fig. 13 <SEP> is an explanatory view of a balance according to a fourth example of modification of the first embodiment. <tb> Fig. 14 <SEP> is an explanatory view of a balance according to a fifth exemplary modification of the first embodiment. <tb> Fig. <SEP> is an explanatory view of a balance according to a sixth exemplary modification of the first embodiment. <tb> Fig. <SEP> is an enlarged view of a collar according to the sixth exemplary modification of the first embodiment. <tb> Fig. 17 <SEP> is an explanatory view of a balance according to a second embodiment. <tb> Fig. 18 <SEP> is an explanatory view of a balance according to a third embodiment. <tb> Fig. 19 <SEP> is an explanatory view of a balance according to a fourth embodiment. <tb> Fig. <SEP> is an explanatory view of a balance according to a fifth embodiment. <tb> Fig. 21 <SEP> is a sectional view taken along the line B-B in FIG. 20. <tb> Fig. 22 <SEP> is an explanatory view of a balance according to a sixth embodiment. <tb> Fig. 23 <SEP> is a graph illustrating the influence of the error in the escapement with respect to walking. <tb> Fig. <SEP> is a graph illustrating walking characteristics caused by the eccentricity of the hairspring and the slippage of the movement of the outer end. <tb> Fig. <SEP> is a graph illustrating gait adjustment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In the following, an embodiment of the present invention will be described with reference to the drawings.

In the following description, a mechanical wristwatch (equivalent to a "timepiece" in the claims) according to the embodiment and a movement inserted into the wristwatch (equivalent to a "piece movement"). "watchmaking" in the claims) will be described, and then a pendulum will be described in detail.

(Timepiece)

In general, reference is made to a machine body including a training part of the timepiece as a "movement". One refers to a state of finished product that is obtained by attaching a dial and hands to movement and placing the movement in a timepiece case as a "complete assembly" of the timepiece. Between the two sides of a main plate that forms the base of the timepiece, reference is made to the side with a glass of the timepiece case, that is to say, the side with the dial, as the "back side" of the movement. Between the two sides of the main stage, reference is made to the side with a rear cover of the timepiece case, that is to say, the opposite side of the dial, as the "front side" of the movement.

FIG. 1 is an external view of a timepiece 1 according to the embodiment.

As illustrated in FIG. 1, the complete assembly of the timepiece 1 of the present embodiment has a timepiece case 3 adapted to have a case back cover (not shown) and a glass 2. Inside the case of timepiece 3, the timepiece 1 includes a movement 100, a dial 11 with an indicator of the information relating to time, and needles comprising a hand of hours 12 indicating hours, a minute hand 13 indicating the minutes and a seconds hand 14 indicating seconds. The dial 11 has an opening for a day indicator 11a which exhibits a number representing the date. In this way, it is possible to check the date in addition to the time using the timepiece 1.

FIG. 2 is a front view viewed from the front side of the movement 100. In FIG. 2, to facilitate understanding of the drawing, some timepiece components making movement 100 are not illustrated and each timepiece component is simplified for illustration.

As illustrated in FIG. 2, the movement 100 of a mechanical timepiece has a main plate 144 composing the base. A winding stem 110 is rotatably inserted into a winding stem guide hole 102 of the main plate 144. At the winding stem 110, the axial position of the winding stem 110 is determined by a winding stem device. switching including an adjusting lever 103, a flip-flop 105, a flip-flop spring 107 and an adjusting lever jumper 109.

Then, if the winding stem 110 rotates, a winding pinion 112 rotates by a rotation of a sliding pinion (not shown). Following the rotation of the winding pinion 112, a ring gear 114 and a ratchet wheel 116 rotate sequentially, thus raising a motor spring (not shown) housed in a barrel 120.

The barrel 120 is rotatably supported between the main plate 144 and a barrel bridge 134 in such a way that the pins (not shown) projecting on both ends of the cylinder axis which is the axle are pivotably supported by the main plate 144 and the barrel bridge 134 respectively. A center swivel 124, a third swivel 126, a second swivel 128 and an escape wheel 130 are rotatably supported between the main deck 144 and a finishing gear deck 136 in such a way that the lugs projecting on the two ends of each axle (not shown) are pivotably supported by the main plate 144 and the gear wheel bridge 136 respectively.

If the barrel 120 rotates restoring the force of the mainspring, following the rotation of the barrel 120, the center mobile 124, the third mobile 126, the second mobile 128 and the mobile 130 escape turn sequentially . The barrel 120, the center mobile 124, the third mobile 126 and the second mobile 128 make up the finishing gear.

If the center mobile 124 rotates, a roadway (not shown) rotates simultaneously on the basis of its rotation and the minute hand 13 (refer to Fig. 1) attached to the roadway is adapted to indicate the "minutes". In addition, based on the rotation of the roadway, an hour wheel (not shown) rotates by the rotation of a minute wheel (not shown) and the hour hand 12 (refer to Fig. 1 ) attached to the minute wheel is adapted to indicate the "hours".

An exhaust / speed control device 140 for controlling the rotation of the gear train is configured to have the escape wheel 130, an anchor 142 and the balance 10.

Teeth 132 are formed on the outer periphery of the escape wheel 130. The anchor 142 is rotatably supported between the main deck 144 and an anchor deck 138, and includes a pair of vanes 142a and 142b. When a pallet 142a of the anchor 142 engages the teeth 132 of the escape wheel 130, the escape wheel 130 is temporarily stopped.

The rocker 10 is rotatably supported between a rocker bridge 104 (equivalent to a "support element" in the claims) and the main plate 144 and turns to a constant cycle. In this way, one pallet 142a and the other pallet 142b of the anchor 142 alternately engage and disengage the teeth 132 of the escape wheel 130. This allows the escape wheel 130 of Exhaust at a constant speed. The balance 10 will be described in detail later.

On the basis of this configuration, after the mainspring (not shown) housed in the barrel 120 is armed using the winding rod 110, a rotational force caused by the disarming of the motor spring causes the barrel 120 to rotate . By the rotation of the barrel 120, the center mobile 124 meshing with it rotates. If the center mobile 124 rotates, the third mobile 126 meshing with it rotates. If the third mobile 126 rotates, the second mobile 128 meshing with it rotates. If the second mobile 128 rotates, the exhaust / speed control device 140 is driven. By driving the exhaust / speed control device 140, the second mobile 128 is controlled to turn once per minute, and the center mobile 124 is controlled to turn once per hour.

(First embodiment)

Subsequently, the rocker 10 according to a first embodiment will be described in detail.

FIG. 3 is a front view of the rocker 10 according to the first embodiment and illustrates a state when viewed from the front side of the movement 100 (see Fig. 2). In fig. 3, a piton 60 and a piton bracket 70 to be described later are illustrated by a two-point line.

FIG. 4 is a sectional view taken along line A-A in FIG. 3. In fig. 4, the upward side from the drawing through the main board 144 is the front side of the movement 100 (refer to Fig. 2) and the down side from the drawing through the main board 144 is the side Back of movement 100. In addition, the rocker bridge 104, the main plate 144 and the piton support 70 are illustrated by the two-point line.

As illustrated in FIG. 3, the rocker 10 mainly includes a rocker wheel 20, a rocker shaft 30, a coil spring 40, a collar 50, the peak 60 and the piton support 70. Hereinafter, each component component of the rocker 10 will be described. In the following description, reference is made to the center of rotation when the balance 10 turns reciprocally as to the central axis O, reference is made to the direction along the central axis O as in the axial direction, reference is made to FIG. the direction orthogonal to the central axis O as to the radial direction, and refers to the direction rotating about the central axis O as the circumferential direction. In addition, in the drawings beside FIG. 4, the center of the spiral spring 40 (center of the Archimedes curve) is illustrated as the central axis C.

The rocker wheel 20 is formed to have an annular portion 21 which is made of metallic material such as brass for example and is formed with a substantially annular shape, and four arms 23 which extend along the direction. radial from the inner peripheral surface of the annular portion 21 to the central axis O.

The annular portion 21 of the balance wheel 20 is arranged coaxially with the central axis O.

Four arms 23 are formed at substantially equal intervals to have a pitch of 90 ° in the circumferential direction respectively. As shown in fig. 4, an insertion hole 25a which is coaxial with the central axis O is formed in a connection region 25 of the four arms 23. The insertion hole 25a of the connection region 25 is externally pressurized to a region for fixing the balance wheel 31 of the balance shaft 30. In this way, the balance wheel 20 is mounted externally and fixed to the balance shaft 30 and can rotate with the balance shaft 30.

The rocker shaft 30 is a rod-shaped axle element of a metallic material such as brass for example. The central axis of the balance shaft 30 is concomitant with the central axis O which is the center of rotation of the balance 10.

The rocker shaft 30 includes the attachment region of the rocker wheel 31 and a collar attachment region 32 which is formed closer to the side of the rocker bridge 104 (upper side in Fig. 4) than the attachment region of the balance wheel 31. The attachment region of the balance wheel 31 and the collar attachment region 32 are formed respectively with a cylindrical shape which is coaxial with the central axis O.

In addition, the rocker shaft 30 includes studs 33 formed so that they are pointed on both ends in the axial direction. The rocker shaft 30 is rotatable about the central axis O in such a way that a stud 33a is pivotably supported by the rocker bridge 104 by a bearing (not shown) and the other stud 33b is pivotally supported by the main plate 144 by a pad (not shown).

The rocker shaft 30 includes a double cylindrical roller 35 closer to the side of the main plate 144 (lower side in Fig. 4) than the rocker wheel 20 in the axial direction. A radially projecting rim portion 36 is formed in the double roll 35. A plateau pin (not shown) is disposed at a radially predetermined outer position in the rim portion 36. The plateau pin impacts a internal peripheral box surface of the anchor 142 to a constant cycle in synchronization with the cycle of the reciprocal rotation of the balance 10, thereby causing the anchor 142 to move reciprocally. As a result, one pallet 142a and the other pallet 142b (refer to Fig. 2 for both) of the anchor 142 are turned over alternately. In this way, as illustrated in FIG. 2, one pallet 142a and the other pallet 142b of the anchor 142 engage and disengage teeth 132 of the escape wheel 130.

As illustrated in FIG. 4, the rocker 10 includes the coil spring 40 closer to the side of the rocker bridge 104 (upper side in Fig. 4) than the rocker wheel 20. As shown in Fig. 3, the spiral spring 40 is a thin-leaf spring made of a metallic material such as steel or nickel for example, and is formed to have a spiral spring-like main body 41 having a plurality of numbers of turns, and an arcuate portion 42 in the outer periphery side of the spiral spring main body 41. The spiral spring 40 is formed such that the spiral shape of the spiral spring main body 41 follows. the curve named Archimedes curve. In this way, when the hairspring 40 is viewed in the axial direction, the hairspring main bodies 41 which are adjacent to each other in the radial direction are arranged to have substantially equal intervals. A portion of the inner circumferential surface in an inner end 43 of the hairspring main body 41 (i.e., an inner end 43 of the hairspring 40) is adapted to be the end securing surface. internal 43a which is fixed to the collar 50 by welding for example. The inner end 43 of the spiral spring 40 is connected to the rocker shaft 30 by the collar 50 by welding the inner end fixing surface 43a of the spiral spring 40 to the collar 50.

The arcuate portion 42 is formed to have a greater radius of curvature than that of the spiral spring main body 41 in the outer peripheral side of the spiral spring main body 41. The outer end 45 of the arcuate portion 42 (i.e., the outer end 45 of the hairspring 40) is attached to the pin 60 (to be described later).

FIG. 5 is an enlarged view of the collar 50 of FIG. 4.

As illustrated in FIG. 5, the collar 50 is an annular element formed of a metallic material such as nickel or a nickel alloy for example, and formed to have a cylindrical portion 51 and a support portion 53 to which the inner end 43 of the spring -spiral 40 is fixed.

The internal diameter of a through hole 51a of the cylindrical portion 51 is smaller than the outer diameter of a collar attachment portion 32 of the rocker shaft 30 to be mounted by pressure externally to the shaft balance 30.

The support portion 53 is formed to protrude radially outwardly into the end of the side of the balance bridge 104 (see Fig. 4, upper side in Fig. 5) of the cylindrical portion. 51. The outer side surface of the support portion 53 serves as the attachment surface 55 to which the inner end fixing surface 43a of the spiral spring 40 is attached by welding or the like.

The central axis of the opening hole 51a of the flange 50 is inclined at an angle 91 with respect to the fastening surface 55 of the support portion 53 in a cross section including its central axis and intersecting the fastening surface 55 (FIG. that is, cross-section taken along the line A-A in Fig. 3). Therefore, when the central axis of the through hole 51a of the flange 50 is concomitant with the central axis O, the through hole 51a of the flange 50 is inserted into the balance shaft 30. When the flange 50 is mounted by pressure of externally and fixedly to the balance shaft 30, the central axis C of the archimedean curve of the spiral spring 40 is inclined at the angle 91 with respect to the central axis O. Then, when the surface of internal end fixing 43a of the spiral spring 40 is inclined at the angle 61 with respect to the central axis O, the spiral spring 40 is fixed to the balance shaft 30.

In this way, it is possible to arrange the inner end 43 of the spiral spring 40 so that it is inclined so that when the inner peripheral surface 40a of the spiral spring 40 is extended in the axial direction (In Fig. 5, a case is illustrated where the inner end fixing surface 43a in the inner peripheral surface 40a of the springs 40 is extended in the axial direction), the collar 50 crosses the central axis O to the angle 91. As described above, the inner end inclining an arrangement structure 80 which can arrange the inner end 43 of the spiral spring 40 to be inclined is disposed in the collar 50 forming the hole opening 51a which is inclined at the angle 81 relative to the attachment surface 55 of the support portion 53. The actuation and the effect when the inner end 43 of the spiral spring 40 is arranged to be inclined will be dec laughs later.

FIG. 6 is an explanatory view of the piton 60 and the piton support 70. In FIG. 6, for an easy understanding, in composition components of the rocker 10, only the spiral spring 40, the piton 60 and the piton support 70 are illustrated. In addition, a tangent to the Archimedean curve in the outer end 45 of the hairspring 40 is illustrated by T (hereinafter referred to as a "tangent T"), and a line radially axial orthogonal to the tangent T is illustrated by R.

As illustrated in FIG. 6, the outer end 45 of the spiral spring 40 is connected to the rocker bridge 104 (refer to Fig. 4) by the bolt 60 and the bolt support 70 which supports the bolt 60.

The stud 60 is configured to have a holding portion 61, a main body 63 and a bolt 65 fixing bolt.

The holding portion 61 is formed with a cylindrical shape, and the outer end 45 of the spiral spring 40 is fixed to its inside by an adhesive or the like for example.

The main body of piton 63 is formed with a rectangular shape. The stud main body 63 has a through hole 63a in which the holding portion 61 can be inserted. The central axis of the through-hole 63a is disposed along the tangent T of the outer end 45 of the spiral spring 40. Inside the through-hole 63a of the main body 63, the outer end 45 of the spring -spiral 40 is arranged for each holding portion 61. At this time, the holding portion 61 is attached to the main body 63 stud inside the hole 63a to be rotatable about the tangent T.

In addition, the securing bolt 65 is screwed from the outside in the radial direction to be attached to the stud main body 63. One end of the securing bolt 65 is arranged to contact the outer peripheral surface of the stud. the holding portion 61 by binding the fixing bolt 65. In this way, when the holding portion 61 rotates about the tangent T at a predetermined angle, the holding portion 61 can be fixed. As a result, it is possible to tilt the outer end portion 45 of the spiral spring 40 about the tangent T.

The stud mount 70 is configured to have an attachment portion 71, a piton support portion 73, a connecting portion 75, and a securing bolt 77.

The attachment portion 71 is formed with a C shape and is arranged coaxially with the central axis O. The attachment portion 71 is attached to the balance bridge 104 (see Fig. 4) by adhesive or by external pressure insertion for example.

The stud support portion 73 is formed to project in the direction of the sprung spring side 40 along the axial direction, at a position corresponding to the outer end 45 of the sprung spring 40. The piton support 73 is connected to the attachment portion 71 by the connecting portion 75.

A radially outward surface in the piton support portion 73 serves as the attachment surface 73a to which the piton 60 is attached. The piton main body 63 of the piton 60 is attached to the attachment surface 73a of the piton support portion 73 by an axle member (not shown). This allows the bolt 60 to be rotatable about the radially axial line R with respect to the bolt support 70.

In addition, the attachment bolt 77 is screwed to be attached to the side surface facing the circumferential direction in the piton support portion 73. One end of the attachment bolt 77 is arranged to enter. in contact with the outer peripheral surface of the axle member (not shown) which pivotsably supports the stud 60 by binding the attachment bolt 77. In this way, when the stud 60 rotates about the radially axial line R at a predetermined angle, the peak 60 can be fixed. As a result, it is possible to tilt the outer end 45 of the spiral spring 40 about the radially axial line R.

As described above, the stud 60 is arranged to be rotatable about the radially axial line R of the spiral spring 40 relative to the stud support 70, and is arranged to be rotatable about the tangent T of the the outer end 45 of the spiral spring 40. In this way, it is possible to arrange the outer end 45 of the spiral spring 40 so that it is inclined so that the stud 60 crosses the central axis O when the inner peripheral surface 40a of the spiral spring 40 is extended in the axial direction. As described above, in the present embodiment, the outer end tilt arrangement structure 90 which can arrange the outer end 45 of the spiral spring 40 to be inclined is disposed in the peak 60 and the pin bracket 70. The actuation and effect when the outer end 45 of the hairspring 40 is arranged to be inclined will be described later.

(Actuation)

Subsequently, in the rocker 10 described above, the actuation when the inner end 43 and the outer end 45 of the spiral spring 40 are arranged so that they are inclined will be described. In the following description, for the reference numbers of each component, refer to FIGS. 1 to 6.

First, when the inner end 43 of the spiral spring 40 is arranged so that it is inclined by the angle θ 1 (refer to Fig. 5) and the value of the angle θ1 is changed from In different ways, the change in the step (second / day) with respect to the oscillation angle (°) of the balance 10 is studied using a simulation. At this time, as shown in FIG. 4, the central axis C of the archimedean curve of the spiral spring 40 is arranged so that it is inclined at the angle θ1 with respect to the central axis O. In this way, on a cross section including the central axis O and the central axis C of the Archimedes curve, a plurality of inner peripheral surfaces 40a of the spiral spring 40 are all parallel to the central axis C of the Archimedes curve, and this is arranged to be inclined by the angle θ1 with respect to the central axis O.

FIG. 7 is a graph illustrating the change in gait with respect to the angle of oscillation of the balance 10 where the vertical axis represents the gait (second / day), the horizontal axis represents the angle of oscillation (°) of the balance 10, the angle θ1 with respect to the central axis O of the inner end 43 of the spiral spring 40 is changed at each value of x1, x2, x3 and x4, and the inner end 43 of the spring spiral 40 is arranged so that it is inclined. Here, each value of x1, x2, x3 and x4, each of which represents the angle θ1 of the inner end 43 of the hairspring 40, is set to become larger in that order.

As illustrated in FIG. 7, in a range where the oscillation angle of the rocker 10 is approximately 250 ° or smaller, it is confirmed that when the angle θ1 of the inner end 43 of the spiral spring 40 becomes larger, the walking increases further. In addition, it is confirmed that when the angle θ1 of the inner end 43 of the spiral spring 40 becomes larger, the rate of increase of the step increases further by following the decrease of the swing angle of the balance. 10.

Then, when the inner end 43 of the spiral spring 40 is arranged so that it is inclined at the angle θ1, the outer end 45 of the spiral spring 40 is inclined at an angle θ 2 in addition to the angle θ1 in the same direction as the direction of inclination of the inner end 43 of the spiral spring 40, and the value of the angle θ2 is changed in different ways, and the change in the step (second / day) relative to the angle of oscillation (°) of the balance 10 is studied using a simulation. At this moment, the central axis C of the archimedean curve of the spiral spring 40 is arranged so that it is inclined by the angle θ1 with respect to the central axis O. Moreover, on a cross section including the central axis O and the central axis C of the Archimedes curve, the angle of inclination of a plurality of inner peripheral surfaces 40a with respect to the central axis O in the spiral spring 40 is arranged to it is inclined outwards from the radial interior to be gradually close to the angle θ2. That is to say, the inner end 43 and the outer end 45 of the spiral spring 40 are arranged to be inclined relative to the central axis O.

FIG. 8 is a graph illustrating the change in gait with respect to the oscillation angle of the balance 10 where the vertical axis represents the step (second / day), the horizontal axis represents the oscillation angle (°) of the balance 10, the angle θ1 with respect to the central axis O of the inner end 43 of the spiral spring 40 is fixed at x3 for example, and the angle θ2 with respect to the central axis O of the outer end 45 of the spiral spring 40 is changed to each value of y1, y2, y3 and y4. Here, each value of y1, y2, y3 and y4, each of which represents the angle θ2 of the outer end 45 of the hairspring 40, is set to become larger in that order.

As illustrated in FIG. 8, in a range where the oscillation angle of the beam 10 is approximately 220 ° or smaller, it is confirmed that when the angle θ2 of the outer end 45 of the spiral spring 40 becomes larger, the walking increases further. In addition, it is confirmed that when the angle θ2 of the outer end 45 of the spiral spring 40 becomes larger, the rate of increase of the step increases further by following the decrease of the swing angle of the balance. 10.

Here, as illustrated in FIG. 23, the error in the exhaust is caused by the decreased torque of the mainspring which is the energy source of the finishing gear. When the oscillation angle of the balance 10 is smaller, the step decreases further. In particular, it is known that the step decreases significantly when the oscillation angle of the balance 10 is 200 ° or smaller.

On the other hand, as illustrated in FIG. 7, the inner end 43 of the spiral spring 40 is arranged to be inclined by the angle θ1, and the angle θ1 of the inner end 43 of the spiral spring 40 increases. In this way, in a range where the oscillation angle is approximately 250 ° or smaller, walking can be increased and the rate of increase of walking can be further increased by following the decrease of the angle of rotation. oscillation of the balance 10. Moreover, as illustrated in FIG. 8, when the inner end 43 of the spiral spring 40 is arranged to be inclined and the outer end 45 of the spiral spring 40 is arranged to be inclined by the angle θ2 in addition to the angle θ1, the angle θ2 of the outer end 45 of the spiral spring 40 increases. In this way, in the range where the oscillation angle is approximately 220 ° or smaller, walking can be increased and the rate of increase of walking can be further increased by following the decrease of the angle of rotation. Therefore, in a range where the step is significantly decreased due to the influence of the error in the escapement and the oscillation angle of the balance is 200 ° or smaller (see FIG. refer to Fig. 23), it is possible to effectively suppress the decrease in gait which is influenced by the error in the exhaust.

According to the present embodiment, when it is extended in the axial direction of the rocker shaft 30, the inner peripheral surface 40a of the spiral spring 40 is formed to cross the central axis O of the axle shaft. Therefore, it is possible to arrange the spiral spring 40 so that it is inclined relative to the central axis O of the balance shaft 30. Here, it is confirmed that the step can be increased in the range of the oscillation angle of the balance 10 where the step is significantly reduced due to the error in the escapement (range where the oscillation angle of the balance is 200 ° or smaller in FIG. 23), when the hairspring 30 is arranged to be inclined with respect to the central axis O of the rocker shaft 30 (refer to the graph in Fig. 7 and the graph in Fig. 8 ). Therefore, it is possible to suppress the decrease in gait which is influenced by the error in the escapement by arranging the spiral spring 40 to be inclined with respect to the central axis O of the spindle. In addition, since the central axis C of the spiral spring 40 is the virtual axial line, it has been difficult to measure the eccentric direction and the eccentricity of the spiral spring 40 in the prior art. On the other hand, since the inclination angle of the hairspring 40 can be easily measured, it is possible to easily adjust the inclination angle of the hairspring 40. Therefore, thanks to the rocker 10 of the present realization, it is possible to reduce the error in the exhaust by easily adjusting the step, and it is possible to obtain the stabilized walking characteristics.

In addition, the flange 50 has the inner end tilt arrangement structure 80 which arranges the inner end 43 of the coil spring 40 such that the inner peripheral surface 40a of the coil spring 40 intersects the central axis O of the balance shaft 30. Thus, it is possible to reliably arrange the spiral spring 40 so that it is inclined relative to the central axis O of the balance shaft 30 In this way, it is possible to suppress the decrease of the step which is influenced by the error in the escape. In addition, since the collar 50 has the internal end tilt arrangement structure 80, it is possible to easily adjust the tilt angle of the coil spring 40 to be any desired angle. by changing the shape of the collar 50 or the like.

In addition, it is possible to arrange the internal end fixing surface 43a so that it is fixed to the collar 50 in the inner peripheral surface 40a of the spiral spring 40 so that it is inclined. relative to the central axis O of the balance shaft 30. Therefore, it is possible to suppress the decrease of the step which is influenced by the error in the exhaust.

In addition, the stud 60 and the stud mount 70 have the outer end tilt arrangement structure 90 which arranges the outer end 45 of the spiral spring 40 such that the inner peripheral surface 40a of the spiral spring 40 crosses the central axis O of the balance shaft 30. Thus, it is possible to reliably arrange the spiral spring 40 so that it is inclined relative to the central axis O of the balance shaft 30. In this way, it is possible to suppress the decrease of the step which is influenced by the error in the exhaust. In addition, since the stud 60 and the stud holder 70 have the outer end tilt arrangement structure 90, it is possible to easily adjust the tilt angle of the coil spring 40 to be any desired angle by changing the shape of the piton 60, the piton holder 70 or the like.

In addition, the outer end inclination arrangement structure 90 is formed to have the stud 60 and the stud mount 70, is arranged to be rotatable about the radially axial line R of the spiral spring 40. and is arranged to be rotatable about the tangent T of the outer end 45 of the hairspring 40. Thus, it is possible to incline the outer end 45 of the hairspring 40 in any desired direction in rotating the stud 60 around the radially axial line R of the spiral spring 40 and around the tangent T of the outer end 45 of the spiral spring 40. In particular, it is possible to arbitrarily adjust the angle of inclination and the tilt direction of the outer end 45 of the hairspring 40 in response to the tilt angle of the inner end 43 when the inner end 43 of the hairspring 40 is arranged to be inclined. In addition, when the bolt 60 is rotated at least around the radially axial line R of the spiral spring 40 or around the tangent T of the outer end 45 of the spiral spring 40, the outer end 45 of the spring spiral 40 is supported by the stud 60. Therefore, in the inner peripheral surface 40a of the spiral spring 40, it is possible to arrange the inner peripheral surface of the outer end 45 to be fixed to the stud 60 of so that it is inclined with respect to the central axis of the balance shaft 30.

Therefore, it is possible to effectively suppress the decrease of the step which is influenced by the error in the exhaust by arranging the inner end 43 of the spiral spring 40 so that it is inclined relative to the central axis O of the rocker shaft 30 and arranging the outer end 45 of the spiral spring 40 so that it is inclined relative to the central axis O of the rocker shaft 30.

Moreover, thanks to the present invention, it is possible to obtain the timepiece movement 100 and the timepiece 1 including the movement 100, which are highly accurate and have few errors in the movement. exhaust, by virtue of the inserted balance 10 described above.

(Each modification example of the first embodiment)

Subsequently, the balance 10 according to each modification example of the first embodiment will be described. In each of the following modification examples of the first embodiment, each form of the inner end tilt arrangement structure 80 will be described.

In the balance 10 of the first embodiment, the inner end inclination arrangement structure 80 is disposed in the collar 50 and a through hole 51a, inclined by the angle θ1 relative to the surface of the fixation 55 of the support portion 53 of the collar 50 is formed. In this way, the inner end 43 of the spiral spring 40 is arranged to be inclined relative to the central axis O (see Fig. 5).

In contrast, the internal end tilt arrangement structure 80 is not limited to the first embodiment. That is, the inner end tilt arrangement structure 80 may be disposed in at least one of the inner end 43 of the coil spring 40, the rocker shaft 30 and the collar 50 The inner end 43 of the spiral spring 40 may be arranged to be inclined with respect to the central axis O by using the inner end tilt arrangement structure 80 of the rocker 10 according to each example of modification which will be described below. In the following description, the configuration elements that are the same as those in the first embodiment will not be described, and only the different elements will be described.

(First example of modification of the first embodiment)

FIG. 9 is an explanatory view of the balance 10 according to a first modification example of the first embodiment, and is an enlarged view of the internal end inclination arrangement structure 80.

As illustrated in FIG. 9, the flange 50 has the through hole 51a which can be mounted externally to the flange attachment portion 32 of the balance shaft 30. In addition, the outer surface of the support portion 53 of the flange 50 serves as the fixing surface 55 to which the inner end fixing surface 43a of the spiral spring 40 is fixed by welding or the like. The attachment surface 55 of the collar 50 is inclined by the angle θ1 with respect to the central axis of the opening hole 51a of the collar 50 in a transverse section which includes the central axis of the opening hole 51a of the collar 50 and crosses the surface. 55 (that is, a cross section equal to the cross-section taken along the line A-A in Fig. 3). Therefore, when the central axis of the through-hole 51a of the flange 50 is concomitant with the central axis O, the through hole 51a of the flange 50 is inserted into the rocker shaft 30 and the flange 50 is mounted externally and fixed at the balance shaft 30. At this moment, when the central axis C of the Archimedean curve of the spiral spring 40 is inclined by the angle θ1 with respect to the central axis O and the fixing surface inner end 43a of the spiral spring 40 is inclined by the angle θ1 with respect to the central axis O, the spiral spring 40 is fixed to the balance shaft 30. In this way, the arrangement structure internal end tilt 80 is disposed in the rocker shaft 30 forming the attachment surface 55 which is inclined by the angle θ1 with respect to the central axis O.

(Second example of modification of the first embodiment)

FIG. 10 is an explanatory view of the balance 10 according to a second modification example of the first embodiment, and is an enlarged view of the internal end inclination arrangement structure 80.

As illustrated in FIG. 10, the rocker shaft 30 includes the rocker attachment portion 31 and the collar attachment portion 32 which is formed closer to the rocker bridge side 104 (refer to Fig. 4, upper side to fig. 10) that the rocker attachment portion 31. The rocker attachment portion 31 is formed to be coaxial with the central axis O.

The neck attachment portion 32 is formed such that its central axis is inclined by the angle θ1 with respect to the central axis O. Therefore, when the central axis of the through hole 51a of the collar 50 is concomitant with the central axis of the collar fixing portion 32 in the rocker shaft 30, when the collar 50 is mounted externally and fixed to the rocker shaft 30, the collar 50 is fixed in a state inclined by the angle θ1 with respect to the central axis O. Therefore, when the central axis C of the archimedean curve of the spiral spring 40 is inclined by the angle θ1 with respect to the central axis O and the internal end fixing surface 43a of the spiral spring 40 is inclined by the angle θ1 with respect to the central axis O, the spiral spring 40 is fixed to the balance shaft 30. In this way, the inner end tilt arrangement structure 80 is disposed in the Router 30 30 forming the collar attachment portion 32 which is inclined by the angle θ1 relative to the central axis O.

(Third modification example of the first embodiment)

FIG. 11 is an explanatory view of the balance 10 according to a third modification example of the first embodiment, and is an enlarged view of the internal end inclination arrangement structure 80. FIG. 12 is an enlarged view of the inner end portion 43 of the spiral spring 40.

As illustrated in FIGS. 11 and 12, the inner end fixing surface 43a of the hairspring spring 40 is arranged to be inclined relative to the inner peripheral surface 40a of the hairspring spring 40 in the inner end 43 of the hairspring spring 40 More specifically, the inner end fixing surface 43a is a tilt surface that is inclined gradually radially inwardly from the side of the balance bridge 104 (see Fig. 4, upper side to Fig. 11 and 12) to the side of main board 144 (refer to Fig. 4, lower side in Fig. 11 and 12). The angle of inclination with respect to the inner peripheral surface 40a of the inner end fixing surface 43a is set to be the angle θ1. In this way, when the internal end fixing surface 43a is welded to the fastening surface 55 of the collar 50, the inner end 43 of the spiral spring 40 is fixed in a state inclined by the angle θ1 with respect to the central axis of the collar 50. Therefore, when the collar 50 is mounted externally and fixed to the balance shaft 30, when the central axis C of the archimedean curve of the spiral spring 40 is inclined by the angle θ1 with respect to the central axis O and the inner peripheral surface 40a of the spiral spring 40 is inclined by the angle θ1 with respect to the central axis O, the spiral spring 40 is fixed to the shaft In this manner, the inner end tilt arrangement structure 80 is disposed in the inner end 43 of the spiral spring 40 by forming the inner end tilting mounting surface 43a.

(Fourth example of modification of the first embodiment)

[0101] FIG. 13 is an explanatory view of the balance 10 according to a fourth modification example of the first embodiment, and is an enlarged view of the inner end tilt arrangement structure 80. In FIG. 13, only the collar 50 and the spiral spring 40 are illustrated.

As illustrated in FIG. 13, the inner end 43 of the coil spring 40 is formed to be twisted by the angle θ1 around the Archimedean curve in a portion adjacent to the inner end fixing surface 43a. In this way, the spiral spring 40 is arranged in a state where the central axis C of the archimedean curve is inclined by the angle θ1 with respect to the central axis O. In addition, in a cross section including the central axis O and the central axis C of the Archimedes curve, the inner peripheral surfaces 40a other than the inner end fixing surface 43a of the spiral spring 40 are arranged to be inclined by the angle θ1 with respect to the central axis O such that all are parallel to the central axis C of the archimedean curve. In this way, the inner end tilt arrangement structure 80 is disposed in the inner end 43 of the hairspring spring 40 by twisting the inner end 43 of the hairspring spring 40.

(Fifth example of modification of the first embodiment)

[0103] FIG. 14 is an explanatory view of the balance 10 according to a fifth modification example of the first embodiment, and is an enlarged view of the inner end tilt arrangement structure 80. In FIG. 14, only the collar 50 and the spiral spring 40 are illustrated.

As illustrated in FIG. 14, the support portion 53 of the collar 50 has a thinned portion 54 in a radially intermediate portion. The attachment surface 55 of the collar 50 may be inclined in any desired direction by causing the thinned portion 54 to deform plastically. In this way, the inner end fixing surface 43a of the spiral spring 40 is fixed in an inclined state with respect to the central axis O in any desired direction. In this way, the internal end tilt arrangement structure 80 is disposed in the support portion 53 of the collar 50 by forming the tapered portion 54 in the support portion 53 of the collar 50.

(Sixth example of modification of the first embodiment)

[0105] FIG. 15 is an explanatory view of the balance 10 according to a sixth exemplary modification of the first embodiment, and is a perspective sectional view of the internal end tilt arrangement structure 80. FIG. 16 is an enlarged view of the collar 50 according to the sixth modification example of the first embodiment.

As illustrated in FIG. 15, the outer peripheral surface of the flange fixing portion 32 of the rocker shaft 30 is formed with a convex spherical surface shape. In addition, the inner peripheral surface of the through hole 51a of the flange 50 is formed with a concave spherical surface shape corresponding to the outer shape of the flange attachment portion 32.

As illustrated in FIG. 16, the cylindrical portion 51 and the support portion 53 of the collar 50 have a slot 56 along the radial direction when viewed in the axial direction. The provision of the slot 56 causes the flange 50 to be shaped with a C shape and allows the cylindrical portion 51 to be elastically deformed to widen its diameter.

As illustrated in FIG. 15, when the collar 50 is mounted at the collar attachment portion 32, the collar 50 is held in the collar attachment portion 32 in such a manner that an elastic force of the cylindrical portion 51 squeezes the attachment portion. At this time, the inner peripheral surface of the through-hole 51a of the flange 50 and the flange-attachment portion 32 are respectively formed with the spherical surface shape and the surface come into contact with each other. Thus, the collar 50 may be inclined around the center of the spherical surface in any desired direction. In this way, the inner end fixing surface 43a of the spiral spring 40 is fixed in an inclined state with respect to the central axis O in any desired direction. As described above, the inner end tilt arrangement structure 80 is disposed in the flange 50 and rocker shaft 30 forming the outer peripheral surface of the shaft flange portion 32 of the shaft beam 30 to have the shape of a convex spherical surface and forming the inner peripheral surface of the opening hole 51a of the collar 50 to have the shape of a concave spherical surface.

(Each embodiment)

Subsequently, the rocker 10 according to each embodiment will be described. In each embodiment described below, each form of the outer end tilt arrangement structure 90 will be described.

In the balance 10 of the first embodiment, the external end inclination arrangement structure 90 is disposed in the peak 60 and the piton support 70. The peak 60 is arranged to be rotatable relative to the pin support 70 around the radially axial line R of the spiral spring 40 and is arranged to be rotatable about the tangent T of the outer end 45 of the spiral spring 40.

In contrast, the outer end tilt arrangement structure 90 is not limited to the first embodiment. That is, the outer end inclination arrangement structure 90 may be disposed in at least one of the outer end 45 of the hairspring 40, the peg 60 and the peg support 70. The outer end 45 of the hairspring spring 40 may be arranged to be inclined with respect to the central axis O using the external end inclination arrangement structure 90 of the beam 10 according to each modification example. which will be described below. In the following description, the configuration elements that are the same as those in the first embodiment will not be described, and only the different elements will be described.

(Second embodiment)

[0112] FIG. 17 is an explanatory view of a rocker 210 according to a second embodiment, and is an explanatory view of the outer end inclination arrangement structure 90. In FIG. 17, for easy understanding, the piton 260 and the main piton body 263 are illustrated by a two-dot line.

As illustrated in FIG. 17, a fixing bolt 265 is screwed so that it is attached to the stud main body 263 from the outside in the radial direction. A screw portion of the attachment bolt 265 is the worm portion 265a which is threaded into a spiral shape.

In addition, an outer peripheral surface in a holding portion 261 of the stud 260 has a worm gear portion 261a which can mesh with the worm portion 265a at a position corresponding to the screw portion. Endless 265a of the mounting bolt 265.

When the worm portion 265a of the attachment bolt 265 meshes with the worm gear portion 261a of the holding portion 261, the attachment bolt 265 rotates. In this way, the holding portion 261 rotates about the tangent T within a through hole 263a with respect to the main body 263 of the bolt. This allows the holding portion 261 to be secured in a turned state. tangent T by a predetermined angle. Thus, it is possible to tilt the outer end 45 of the spiral spring 40 about the tangent T. In this way, the outer end tilt arrangement structure 90 is disposed in the piton 260 forming the worm portion 265a in the attachment bolt 265 and forming the worm gear portion 261a on the outer peripheral surface of the holding portion 261. In particular, the tilt arrangement structure of outer end 90 of the present embodiment is advantageous in that it is possible to carefully adjust the angle of rotation of the holding portion 261 (i.e., the angle of inclination of the outer end 45 of the spiral spring 40) in response to the angle of rotation of the worm portion 265a.

(Third embodiment)

[0116] FIG. 18 is an explanatory view of a rocker 310 according to a third embodiment, and is an explanatory view of the external end inclination arrangement structure 90.

As illustrated in FIG. 18, a holding portion 361 of a stud 360 is formed with a spherical shape. An insertion hole 366 is formed in the holding portion 361 to allow the outer end 45 of the hairspring 40 to be inserted and secured thereto. An actuating portion 367 is erected along the axial direction from the holding portion 361 to the side of the balance bridge 104 (see Fig. 4, upper side in Fig. 18).

An attachment surface 373a of a stud support portion 373 has a concave spherical surface portion corresponding to the spherical surface of the holding portion 361.

In addition, a support piece 374 with a rectangular parallelepiped shape is disposed outside in the radial direction of the piton support portion 373 to oppose the attachment surface 373a of the piton support portion. 373. A surface opposing the attachment surface 373a of the stud support portion 373 in the support piece 374 is an attachment surface 374a. Similar to the attachment surface 373a of the stud support portion 373, the attachment surface 374a of the support piece 374 has a concave spherical surface portion corresponding to a spherical surface of the holding portion 361. The workpiece support 374 may be attached to the stud support portion 373 from the outside in the radial direction using a plurality of securing bolts 365.

The holding portion 361 of the pin 360 is rotatably interposed between the pin support portion 373 and the holding piece 374. At this time, the holding portion 361 is interposed between the concave spherical surface portion of the stud support portion 373 and the concave spherical portion of the support piece 374. Thus, the holding portion 361 is rotatable about the center of the spherical surface in any desired direction. Then, the actuating portion 367 is moved and the holding portion 361 of the stud 360 rotates so that the outer end 45 of the spiral spring 40 is inclined at any desired angle. Hereinafter, a plurality of securing bolts 365 are threaded so that the outer end 45 of the hairspring 40 is fixed in an inclined state in any desired direction relative to the central axis O. As described above, the outer end tilt arrangement structure 90 is disposed in the peak 360 and the piton support 70 forming the retaining portion 361 of the peak 360 to have the shape of a spherical surface and forming the concave spherical surface portion on the attachment surface 373a of the piton support portion 373 and the attachment surface 374a of the support piece 374.

(Fourth embodiment)

[0121] FIG. 19 is an explanatory view of a rocker 410 according to a fourth embodiment, and is an explanatory view of the external end inclination arrangement structure 90.

As illustrated in FIG. 19, a holding portion 461 of a peg 460 is formed with a spherical shape. The holding portion 461 has an insertion hole 466 to allow the outer end portion 45 of the hairspring 40 to be inserted and secured thereto.

[0123] An attachment surface 473a of a peak support portion 473 is arranged to face the side of the main stage 144 (refer to Fig. 4, lower side in Fig. 19), and has a concave spherical surface portion corresponding to a spherical surface of the holding portion 461.

In addition, a support piece 474 with a rectangular parallelepipedal shape is disposed in the side of the main plate 144 of the piton support portion 473 (see Fig. 4, lower side in Fig. 4). 19) for opposing the attachment surface 473a of the pin support portion 473. A surface opposing the attachment surface 473a of the pin support portion 473 in the support piece 474 is an attachment surface 474a. . Similar to the attachment surface 473a of the piton support portion 473, the attachment surface 474a of the support piece 474 has a concave spherical surface portion corresponding to a spherical surface of the holding portion 461. The workpiece The support member 474 may be attached to the stud support portion 473 from the main deck 144 side (refer to Fig. 4, lower side in Fig. 19) using a plurality of securing bolts 465.

The holding portion 461 of the pin 460 is rotatably interposed between the pin support portion 473 and the support piece 474. At this time, the holding portion 461 is interposed between the concave spherical surface portion of the piton support portion 473 and the concave spherical surface portion of the support piece 474. Thus, the holding portion 461 is rotatable about the center of the spherical surface in any desired direction. Then, the holding portion 461 of the pin 460 rotates so that the outer end 45 of the hairspring 40 is inclined at any desired angle. Hereinafter, a plurality of securing bolts 465 are tightened so that the outer end 45 of the hairspring 40 is fixed in an inclined state in any desired direction relative to the central axis O. As described above, the outer end inclination arrangement structure 90 is disposed in the stud 460 and the stud mount 70 forming the holding portion 461 of the stud 460 to have the shape of a spherical surface and forming the form concave spherical surface on the attachment surface 473a of the piton support portion 473 and the attachment surface 474a of the support piece 474.

(Fifth embodiment)

[0126] FIG. 20 is an explanatory view of a rocker 510 according to a fifth embodiment, and is an explanatory view of the outer end inclination arrangement structure 90. FIG. 21 is a sectional view taken along line B-B in FIG. 20.

As illustrated in FIG. 20, a stud holder portion 573 of the stud holder 70 is formed to protrude radially outwardly. An adjustment bolt 68 is screwed to be attached to the stud support portion 573 along the axial direction.

A peg 560 is formed with a cylindrical shape and is arranged along the axial direction relative to the piton support portion 573. The piton 560 is held by the piton support portion 573 in such a manner. that a point of a securing bolt 565 tightened to the piton support portion 573 contacts the piton 560 from the outside in the radial direction. On an end surface on the side of the main plate 144 (refer to Fig. 4, lower side in Fig. 20) of the stud 560, a groove-shaped holding portion 561 is formed to be a hollow in the axial direction to extend along the tangent T of the outer end 45 of the hairspring 40. The outer end 45 of the hairspring 40 is attached to the holding portion 561.

As illustrated in FIG. 21, the outer end 45 of the spiral spring 40 serves as an adjusting portion 45a in which its portion is shaped to be twisted and to face in the axial direction. The tip of the adjustment bolt 68 is in contact with the adjustment portion 45a. In addition, the area between the attachment portion 45b attached to the holding portion 561 and the adjusting portion 45a in the outer end 45 of the hairspring spring 40 serves as an elastic deformation portion 45c that can be elastically deformed. in the axial direction.

By tightening the adjustment bolt 68, the elastic deformation portion 45c is elastically deformed and the adjusting portion 45a is moved to the side of the main platen 144 (refer to Fig. 4, side lower in Fig. 21). In addition, by loosening the adjustment bolt 68, the adjusting portion 45a is moved toward the side of the rocker bridge 104 (see Fig. 4, upper side in Fig. 21) by a restoring force. elastic of the elastic deformation portion 45c. In this way, the adjustment bolt 68 rotates to adjust the position of the adjustment portion 45a in the axial direction. Accordingly, the outer end 45 of the coil spring 40 is fixed in an inclined state in any desired direction relative to the central axis O. As described above, the tilt arrangement structure of the outer end 90 is disposed in the stud mount 70 and the coil spring 40 by arranging the adjustment bolt 68 in the piton support portion 573 of the stud mount 70 and forming the adjustment portion 45a and the part of elastic deformation 45c in the outer end 45 of the spiral spring 40.

(Sixth embodiment)

[0131] FIG. 22 is an explanatory view of a beam 610 according to a sixth embodiment, and is an explanatory view of the external end inclination arrangement structure 90.

As illustrated in FIG. 22, a stud holder portion 673 of the stud holder 70 is formed with a plate shape projecting in the radial direction.

A peg 660 is formed with a cylindrical shape and is arranged along the axial direction relative to the piton support portion 673. The piton 660 is held by the piton support portion 673 in such a manner. a point of a securing bolt 665 tightened to the piton support portion 673 contacts the piton 660 from the outside in the radial direction. On an end surface on the main deck side 144 (refer to Fig. 4, lower side in Fig. 22) of the piton 660, a groove-like holding portion 661 is formed to be a cavity. in the axial direction to extend along the tangent T of the outer end 45 of the hairspring 40. The outer end 45 of the hairspring 40 is attached to the holding portion 661.

A brittle portion 62 which has a diameter smaller than that of the other parts is formed in an axially intermediate portion of the bolt 660. A portion closer to the side of the main plate 144 (refer to Fig. 4). , lower side in Fig. 22) that the fragile portion 62 of the bolt 660 can be inclined in any desired direction by elastically deforming the fragile portion 62. In this way, the outer end 45 of the spring spiral 40 is fixed in an inclined state in any desired direction relative to the central axis O. As described above, the outer end inclination arrangement structure 90 is disposed in the piton 660 in forming the fragile portion 62 in the piton 660.

In any of the respective embodiments described above, when the inner end 43 of the spiral spring 40 is arranged to be inclined, it is possible to arbitrarily adjust the angle of rotation. inclination and tilt direction of the outer end 45 of the spiral spring 40 in response to the tilt angle of the inner end 43. Therefore, it is possible to obtain the same effect as that of the first embodiment. That is, it is possible to effectively suppress the decrease in walking that is influenced by the error in the exhaust.

The technical scope of the present invention is not limited to the embodiments described above and may also be varied in a variety of ways in a range without departing from the spirit of the present invention.

The inner end tilt arrangement structure 80 and outer tilt inclination arrangement structure 90 are not limited to the first embodiment described above, each modification example of the first embodiment and each embodiment. In addition, the inner end tilt arrangement structure 80 according to each modification example of the first embodiment and the outer end tilt arrangement structure 90 according to each embodiment can be arbitrarily combined to create the pendulum.

In the first embodiment, the inner end 43 of the spiral spring 40 and the outer end 45 of the spiral spring 40 are arranged so that they are inclined with respect to the central axis O. However, when the inner peripheral surface 40a of the hairspring 40 is extended in the axial direction of the rocker shaft 30, at least the inner end 43 of the hairspring 40 can be arranged to be inclined such that at least a part in the inner peripheral surface 40a of the spiral spring 40 crosses the central axis O of the rocker shaft 30.

Moreover, in a range without departing from the spirit of the present invention, it is possible to appropriately replace the configuration elements in the embodiments described above with the configuration elements well. known.

Claims (7)

1. Pendulum (20) comprising: a rocker shaft (30) which is rotatably arranged with respect to the support member (104) and to which a rocker wheel (20) is mounted externally and fixedly; and a spiral spring (40) which is formed according to the Archimedean curve and in which its inner end (43) is connected to the rocker shaft (30) and its outer end (45) is connected to the spring element; support (104), wherein when an inner peripheral surface (40a) of the coil spring (40) is extended in the axial direction of the rocker shaft (30), at least a portion in the inner peripheral surface (40a) is formed to intersect the central axis (O) of the balance shaft (30). 2. Pendulum (20) according to claim 1, wherein the inner end (43) of the hairspring (40) is connected to the rocker shaft (30) by a collar (50) which is externally mounted and fixed to the rocker shaft (30) , and wherein in at least one of the inner end (43) of the hairspring (40), the balance shaft (30) and the collar (50), an internal end tilt arrangement structure ( 43) is created in which the inner end (43) of the spiral spring (40) is arranged so that when the inner peripheral surface (40a) of the spiral spring (40) is extended in the axial direction, at least a portion in the inner circumferential surface (40a) intersects the central axis (O) of the balance shaft (30). 3. Pendulum (20) according to claim 2, wherein the inner end tilt arrangement structure (43) is disposed such that when the inner end fixing surface attached to the collar (50) in the inner peripheral surface (40a) of the spiral spring (40) is extended in the axial direction, the inner end (43) of the spiral spring (40) crosses the central axis (O) of the balance shaft (30). 4. Pendulum (20) according to any one of claims 1 to 3, wherein the outer end (45) of the hairspring (40) is connected to the support member (104) by a peg (60) and a peg support (70) which supports the peg (60), and wherein an outer end tilt arrangement structure is provided in which the outer end (45) of the spiral spring (40) is disposed such that when the inner peripheral surface (40a) of the spiral spring (40) is extended to at least one of the outer end (45) of the hairspring (40), the peg (60) and the peg support (70) in the axial direction, at least a portion in the surface internal peripheral (40a) crosses the central axis (O) of the balance shaft. 5. Pendulum (20) according to claim 4, wherein the outer end tilt arrangement structure (45) is formed to have the peak (60), wherein the stud (60) is arranged to be rotatable about a radially axial line of the spiral spring (40) relative to the stud mount (70) and is arranged to rotate about a tangent (T) relative to at the Archimedes curve in the outer end (45) of the spiral spring (40), and wherein the outer end (45) of the hairspring (40) is supported by the pin (60) when the pin (60) rotates at least about the radially axial line of the hairspring (40) or around the tangent (T) of the outer end (45) of the spiral spring (40). 6. Movement (100) of timepiece (1) wherein the rocker (20) according to claim 1 is inserted. 7. Timepiece (1) comprising: the movement (100) of timepiece (1) according to claim 6.