Escapement comprising an anchor, timepiece movement and timepiece comprising such an escapement.

专利摘要:
An object of the invention is to propose an escapement making it possible to improve the efficiency of the transmission of energy, a timepiece movement comprising the escapement and a timepiece comprising the timepiece movement. The escapement (1) comprises an escape wheel (11), a double plate (53) which is intended to equip a pendulum and pivot on a pivot axis (O), as well as an anchor (12) which can pivot on an anchor pin (33). The double plate (53) comprises a plate pin (57) which comes into contact with the anchor (12) in response to a pivoting movement of the double plate (53) and causes a pivoting movement of the anchor (12) on the anchor axis (33), and a pulse pallet (58) which can come into contact with a tooth (23) of the escape wheel (11). The anchor (12) comprises two pallets which are an entry pallet (45) and an exit pallet (38).
公开号:CH708390B1
申请号:CH01145/14
申请日:2014-07-25
公开日:2020-04-30
发明作者:koda Masayuki；Suzuki Shigeo；Hisashi Fujieda
申请人:Seiko Instr Inc；
IPC主号:

专利说明:

BACKGROUND OF THE INVENTION
1. Field of the invention
The present invention relates to an escapement, as well as a watch movement and a timepiece comprising the escapement.
2. Description of the related art
In general, a mechanical watch includes an escapement to control the rotation of a barrel, a center mobile, an average mobile and a second mobile which form a cog. The escapement mainly comprises an escape wheel, a double plate fitted to a pendulum which moves in pivoting around a pendulum axis and an anchor which is displaceable in pivoting on an anchor axis.
The double plate comprises a plate pin which comes into contact with the anchor, and moves in pivoting with the balance using the energy accumulated in a balance spring. The anchor includes an input pallet and an output pallet which can disengage from a tooth of the escape wheel and move in pivoting on the anchor axis thanks to the energy of the balance spring transmitted at anchor via the dowel pin.
If the anchor moves pivotally around the axis of the pallet, the input pallet and the output pallet are released alternately from the tooth of the escape wheel. When the input pallet and the output pallet of the anchor engage the tooth of the escape wheel, the rotation of the escape wheel is temporarily stopped. In addition, when the input pallet and the output pallet disengage from the tooth of the escape wheel, the escape wheel pivots. These operations are repeated continuously so that the mechanical watch counts the time.
Incidentally, in general, the energy of the balance spring is supplied by a main spring disposed in the barrel via the gear train and the exhaust.
For example, the publication of European patent application No. 0018796 (patent document 1) discloses the exhaust comprising the escape wheel having an escape pinion, the anchor having the inlet pallet, the output pallet and a third pallet (pallet 26), the double tray having a tray pin and a pulse pallet (pallet 25). According to a technology disclosed in patent document 1, when the pendulum and the double-plate pivot in a clockwise direction, the tooth of the escape wheel comes into contact with the impulse palette so as to supply the balance spring with energy. In addition, when the balance wheel and the double plate move in a pivoting direction anticlockwise, the escape pinion of the escape wheel comes into contact with the third pallet so as to supply the spring. balance in energy via the anchor.
In the related art, however, it is necessary to ensure that the third pallet comes into contact with the exhaust pinion in the anchor. There is therefore a tendency to increase the size of the anchor. Furthermore, in order to allow the exhaust pinion and the third vane to come into contact with each other, there is a tendency to increase the size of the exhaust pinion. This increases the resistance to friction due to viscosity when the anchor and the escapement wheel pivot. In addition, since the increase in the dimensions of the anchor and of the escape wheel increases their weight, the resistance to friction due to the mass in the anchor axis or a bearing of a portion d the axis of the escape wheel increases. This increase in friction resistance due to viscosity and in friction resistance due to mass results in a loss of energy in the exhaust.
In addition, the increased weight of the anchor and the escape wheel increases the moment of inertia. Consequently, a movement slows down when the anchor and the escapement wheel pivot. This decreases an impact domain when the anchor and the escape wheel collide with the ellipse and it is therefore not possible to transmit energy efficiently.
According to the above description, in the related art, the problem lies in that the efficiency of the energy transmission in the exhaust must be improved thanks to the increase in size and weight of the anchor and the escape wheel.
SUMMARY OF THE INVENTION
Therefore, the present invention aims to provide an escapement which can increase the efficiency of energy transmission, a timepiece movement comprising the escapement and a timepiece comprising the timepiece movement.
In order to solve the problem described below, an exhaust according to the present invention is as defined in the appended claim 1.
According to the present invention, the anchor comprises two pallets. Therefore, compared to the related art comprising three pallets, a pallet can be omitted and a space for fixing the omitted pallet can be eliminated. In addition, compared to the related art, the pallet and an exhaust gear should not come into contact with each other. It is therefore possible to reduce the diameter of the exhaust pinion. This makes it possible to reduce the dimensions and the weight of the anchor and the escape wheel. Therefore, it is possible to decrease the friction resistance due to viscosity and the friction resistance due to mass when the anchor and the escapement wheel turn. In addition, the reduced weight of the anchor and the escape wheel reduces the moment of inertia, compared to the related art. The anchor can therefore pivot quickly. In this way, an impact domain is widened when the anchor collides with the plate pin and the escape wheel collides with the impulse paddle. Therefore, it is possible to transmit energy efficiently. According to the above description, it is possible to improve the efficiency of the energy transmission from the escape wheel to the balance wheel due to the smaller size and the lower weight of the anchor and the wheel. exhaust.
In addition, the double plate includes the plate pin which comes into contact with the anchor in response to the pivoting movement of the double plate and causes the pivoting movement of the anchor on the anchor axis. , and the impulse paddle which can come into contact with the tooth of the escape wheel. So, for example, even in the case where the exhaust which requires lubrication of the paddle and the tooth of the escapement wheel, it is possible to suppress the diffusion of oil on a contact portion between the ankle platform and anchor. Consequently, it is possible to ensure stable operation of a speed regulator comprising the exhaust and the balance wheel by preventing the adhesion of the oil or an increase in resistance due to the viscosity caused by the deterioration of the adherent oil. It is therefore possible to prevent a deterioration of the adjustment precision.
In addition, without depending on a position of the plate pin, it is possible to adjust a desired position of the impulse paddle, a desired outside diameter of the escape wheel and a desired separation distance between the pivot axis of the double plate and the center of rotation of the escape wheel. In this way, it is possible to set a desired impact area when the tooth of the escape wheel and the impulse paddle collide with each other. It is therefore possible to adjust a desired balance between the efficiency of the energy transmission from the exhaust and the adjustment precision.
In the case where the exhaust is according to claim 2, when the double plate rotates in one direction, the first pallet and the escape wheel are released from one another, the tooth of the wheel and the impulse paddle coming into contact with each other. Therefore, it is possible to provide energy by directly applying an impact to the impulse paddle from the escape wheel. In addition, when the double plate swivels in the other direction, the second pallet and the escape wheel are released from one another, the tooth of the escape wheel being caused to slide on the surface of slip. It is therefore possible to have the anchor pivot on the anchor axis by moving the second pallet. Therefore, it is possible to provide energy by applying impact to the chain pin from the escape wheel via the anchor.
When the exhaust is according to claim 3, a position in which the first pallet and the second pallet come into contact with the tooth of the escapement wheel and a position in which the anchor comes into contact with the ankle plate are offset from each other in the direction of the pivot axis of the double plate. Therefore, for example, including by lubricating the second pallet having the sliding surface, it is possible to reliably suppress the diffusion of oil on a contact portion between the plate pin and the anchor. In addition, in the axial direction, the first anchor body can be disposed in a position corresponding to the tooth of the escape wheel, the second anchor body being able to be disposed in a position corresponding to the plate pin. Therefore, the first pallet and the second pallet which are held by the first anchor body can be prevented from being extended in the axial direction. This allows the weight of the first pallet and the second pallet to be reduced and it is possible to reduce the bending movement acting on the first pallet and the second pallet when the first pallet and the second pallet come into contact with the tooth of the escape wheel. Therefore, it is possible to provide an excellent exhaust which can have both reduced weight and improved durability.
When the exhaust is according to claim 4, in the axial direction, the impulse paddle can be arranged in a position corresponding to the first tooth of the first escapement wheel, and the second paddle can be arranged in a position corresponding to the second tooth of the second escape wheel. This can prevent the impulse pallet held by the double plate and the second pallet held by the anchor from being extended in the axial direction. Consequently, it is possible to reduce the weight of the impulse pallet and the second pallet, and it is possible to reduce the bending movement acting on the impulse pallet and the second pallet when the impulse pallet and the second pallet comes into contact with the tooth of the escape wheel.
In addition, the second escape wheel is adapted to have a diameter less than that of the first escape wheel. Therefore, it is possible to further increase a torque generated in the anchor compared to a torque generated in the second escape wheel. In addition, the reduced weight of the second pallet can reduce the moment of inertia of the anchor. Therefore, when energy is supplied by applying impact to the chain pin from the escape wheel via the anchor, it is possible to improve the efficiency of the energy transmission.
In addition, the first tooth of the first escape wheel and the second tooth of the second escape wheel can be adapted to have different shapes which are suitable for the respective teeth. It is therefore possible to improve the resistance of the first tooth of the first escape wheel and of the second tooth of the second escape wheel.
In addition, the first tooth of the first escapement wheel with which the impulse paddle comes into contact and the second tooth of the second escapement wheel from which the second paddle emerges are arranged in positions respectively. offset from each other in the axial direction. So, for example, even in the exhaust requiring lubrication of the anchor and the tooth of the escapement wheel, it is possible to reliably suppress the diffusion of oil towards the contact portion between the ankle. and anchor and it is also possible to reliably suppress the diffusion of oil to the impulse paddle.
When the exhaust is according to claim 5, the second tooth extends in the direction of the pivot axis of the double plate. Therefore, compared to a case where the second tooth is formed as a gear, it is possible to decrease the weight of the second tooth. This can reduce the moment of inertia of the escape wheel. Consequently, it is possible to improve the efficiency of the transmission of energy from the escape wheel to the balance wheel.
In addition, it is possible to easily adjust a separation distance of the second tooth by adjusting a thickness of the second tooth. It is therefore possible to easily ensure a spacing between the second pallet and the second tooth. Therefore, it is possible to provide an escape wheel with excellent design flexibility.
When the exhaust is according to claim 6 or claim 7, the second tooth slides on the sliding surface of the second pallet, after which the second pallet continues to slide on the impulse surface of the second tooth. In this way, it is possible to apply a significant torque to the balance wheel via the anchor. Consequently, the energy transmitted to the balance wheel can be further improved by the escape wheel which has both the first tooth and the second tooth which can apply a direct impact to the impulse paddle described above.
When the exhaust is according to claim 8, the double plate comprises the first double plate body which holds the plate pin and the second double plate body which holds the impulse paddle. It is therefore possible to distribute the stress when the plate pin comes into contact with the anchor and the stress when the impulse paddle comes into contact with the tooth of the escape wheel, respectively, at the level of the first body of double tray and the second double tray body. In addition, for example, even if the plate pin and the impulse pallet are fixed to the double plate by force and, in addition, the double plate is fixed to the balance axis by force, it is possible to distribute the stress generated during the forced mounting at the level of the first double-plate body and the second double-plate body. Therefore, it is possible to ensure the rigidity of the double plate and it is possible to provide an exhaust whose durability is excellent.
When the exhaust is according to claim 9, the anchor comprises the small plate with which the dart comes into sliding contact. Therefore, even when the platter pin emerges from the fork entry, it is possible to prevent the pivoting movement of the anchor. Therefore, it is possible to prevent an abnormal operation, called shaking, in which the tray pin comes into contact with a surface on the outside of the fork entry after the tray pin emerges from the fork entry. fork, the movement of the platform pin being hampered by the anchor and the pivoting movement of the balance being stopped.
In addition, an amount of engagement of the first pallet and the second pallet with the tooth of the escape wheel is ensured so as to obtain a required quantity predetermined or greater. In this way, it is possible to prevent the abnormal operation according to so-called semi-shaking phenomenon. In an operating state where the first paddle and the second paddle are not supposed to disengage from the tooth of the escapement wheel in the intended operation at the origin of the escapement, for example, in a state in which the chainring pin is not supposed to enter the fork entry, strong disturbances lead to the release of the first pallet and the second pallet from the tooth of the escape wheel, the escape wheel falling on the surface sliding the second pallet, for example. The impact is transmitted from the escape wheel to the anchor, the latter being caused to pivot. As a result, a kite-shaped portion or (lucane) compresses the plateau pin. In addition, the sting compresses the small tray. Consequently, the balance is compressed by the anchor in the radial direction of the balance, the pivoting movement of the balance being finally stopped.
When the exhaust is according to claim 10, the engagement surface of the pallet is inclined relative to the second straight line at a predetermined angle in the direction of rotation of the escape wheel. So, if the tooth of the escape wheel and the pallet engage each other, a torque acts on the pallet so that the torque of the escape wheel pulls the pallet in the side of the wheel. 'exhaust. In this way, it is possible to stabilize a state of engagement between the tooth of the escape wheel and the pallet. Therefore, for example, it is possible to prevent the engagement position of the first pallet and the second pallet with the tooth of the escape wheel from being deflected due to the disturbance. Therefore, it is possible to prevent an abnormal operation in which the anchor is caused to move in pivoting due to the disturbance, the small plate and the dart coming into contact with each other to interfere with the pendulum, the free vibration of the pendulum being consequently prevented.
In addition, a timepiece movement of the present invention includes the escapement described above. In addition, a timepiece of the present invention includes the timepiece movement described above.
According to the present invention, it is possible to provide the high-performance timepiece movement and the high-performance timepiece which can improve the efficiency of energy transmission and whose setting precision is excellent.
According to the present invention, the anchor comprises two pallets. Therefore, compared to the anchor in the related art comprising three pallets, a pallet can be omitted and a space for fixing the omitted pallet can be gained. In addition, compared to the related art, the pallet and an exhaust gear should not come into contact with each other. It is therefore possible to reduce the diameter of the exhaust pinion. This makes it possible to reduce the dimensions and the weight of the anchor and the escape wheel. Therefore, it is possible to decrease the friction resistance due to viscosity and the friction resistance due to mass when the anchor and the escapement wheel pivot. In addition, the reduced weight of the anchor and the escape wheel reduces the moment of inertia compared to the related art. The anchor can therefore move quickly in pivoting. In this way, an impact domain is widened when the anchor collides with the plate pin and the escape wheel collides with the impulse paddle. Therefore, it is possible to transmit energy efficiently. According to the above description, it is possible to improve the efficiency of the transmission of energy from the escape wheel to the balance wheel due to the reduced size and the reduced weight of the anchor and the wheel. exhaust.
In addition, the double plate includes the plate pin which comes into contact with the anchor in response to the pivoting movement of the double plate and causes the anchor to pivot on the anchor axis, and the impulse pallet which can come into contact with the tooth of the escape wheel. So, for example, even in the exhaust requiring lubrication of the pallet and the tooth of the escape wheel, it is possible to suppress the diffusion of oil on the contact portion between the plate pin and the 'anchor. Consequently, it is possible to ensure stable operation of a speed regulator comprising the exhaust and the balance wheel by preventing the adhesion of the oil or an increase in resistance due to the viscosity caused by the deterioration of the adherent oil. It is therefore possible to prevent deterioration of the adjustment accuracy.
In addition, without depending on a position of the plate pin, it is possible to adjust a desired position of the impulse paddle, a desired outside diameter of the escape wheel and a desired separation distance between the pivot axis of the double plate and the center of rotation of the escape wheel. In this way, it is possible to set a desired impact area when the tooth of the escape wheel and the impulse paddle collide with each other. It is therefore possible to adjust a desired balance between the efficiency of the energy transmission from the exhaust and the adjustment precision.
BRIEF DESCRIPTION OF THE SKETCHES
[0033]<tb> <SEP> Fig. 1 is a plan view when a watch movement is seen from a front side.<tb> <SEP> Fig. 2 is a perspective view of an exhaust.<tb> <SEP> Fig. 3 is a plan view of an escape wheel.<tb> <SEP> Fig. 4 is a perspective view of a double tray.<tb> <SEP> Fig. 5 is a plan view of the double tray and of an anchor.<tb> <SEP> Fig. 6 is a perspective view of an anchor body.<tb> <SEP> Fig. 7 is a diagram illustrating an operation of the exhaust.<tb> <SEP> Fig. 8 is a diagram illustrating an operation of the exhaust.<tb> <SEP> Fig. 9 is a diagram illustrating an operation of the exhaust.<tb> <SEP> Fig. 10 is a diagram illustrating an operation of the exhaust.<tb> <SEP> Fig. 11 is a diagram illustrating an operation of the exhaust and is an enlarged view of the double plate and of a fork entry.<tb> <SEP> Fig. 12 is a diagram illustrating an operation of the exhaust.<tb> <SEP> Fig. 13 is a diagram illustrating an operation of the escapement and is an enlarged view of the double plate and of the fork entry.<tb> <SEP> Fig. 14 is a diagram illustrating an operation of the exhaust.<tb> <SEP> Fig. 15 is a perspective view of an exhaust according to a second embodiment.<tb> <SEP> Fig. 16 is a plan view of an anchor according to a second embodiment.<tb> <SEP> Fig. 17 is a perspective view of an exhaust according to a third embodiment.<tb> <SEP> Fig. 18 is a plan view of a second escape wheel according to a third embodiment.<tb> <SEP> Fig. 19 is a perspective view of an exhaust according to an amending example of the third embodiment.<tb> <SEP> Fig. 20 is a perspective view of a double plate configuring an exhaust according to a fourth embodiment.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
First embodiment
An embodiment of the present invention will be described below with reference to the sketches.
Here, a mechanical watch according to the embodiment will first be described, after which an escapement will be described in detail.
In general, a machine body comprising a drive portion of a timepiece is called "movement". A state of a finished product obtained by attaching a dial and hands to the movement and placing the movement in a watch case is called "complete assembly" of the watch. Between the two sides of a main plate configuring a substrate of the watch, a side provided with the glass of the watch case, that is to say a side having the dial is called "rear side" of the movement. Between the two sides of the main plate, a side with a back cover of the watch case, that is to say a side opposite the dial is called "front side" of the movement.
[0037] FIG. 1 is a plan view when the movement 101 of a watch 100 (corresponding to a "watch movement" in the claims) is seen from the front side.
As illustrated in FIG. 1, the timepiece 100 comprises the movement 101. The movement 101 has a main plate 102. A winding rod guide hole 103 is formed in the main plate 102. A winding rod 104 is rotatably mounted at the inside the guide hole of the winding stem 103.
A switching device (not illustrated) comprising an adjustment lever, a portable player and a portable support is arranged in a rear side of the movement 101 (rear side of the paper surface of FIG. 1). This switching device determines an axial position of the winding stem 104.
A second mobile 106, a third mobile 107, a central mobile 108 and a cylinder wheel 110 form a train 105, an exhaust 1 and a speed regulator 2 which controls the rotation of the train 105 being arranged on the front side of movement 101 (front side of the paper surface of Fig. 1).
The cylinder wheel 110 has a main spring 111. If the winding rod 104 rotates, a clutch wheel (not shown) rotates and the main spring 111 is wound up via a winding pinion, a meeting wheel and a ratchet (not shown). Then, the cylinder wheel 110 rotates under the effect of a rotational force generated when the main spring 111 is unwound, the central mobile 108 also rotating.
The central mobile 108 has a central pinion meshing with a cylinder gear (not shown) of the cylinder wheel 110 and a central gear (none of these elements being illustrated). If the central mobile 108 rotates, the third mobile 107 rotates.
The third mobile 107 has a third pinion (not shown) meshing with the central gear of the central mobile 108 and a third gear (none of these elements being illustrated). If the third mobile 107 rotates, the second mobile 106 rotates.
The second mobile 106 has a second pinion (not shown) meshing with the third gear of the third mobile 107 and a second gear (none of these elements being illustrated). The second mobile 106 rotates, thus driving the exhaust 1 and the speed regulator 2.
The exhaust 1 includes an escape wheel 11 meshing with the second mobile 106 and an anchor 12 which releases the escape wheel 11 for its regular rotation.
The cruise control 2 is a mechanism for regulating the speed of the exhaust 1 which has a balance 5.
Then, the exhaust 1 and the speed regulator 2 are driven, thus controlling the second mobile 106 so as to rotate once per minute and controlling the central mobile 108 so as to rotate once per hour.
Exhaust
Next, the exhaust 1 will be described.
[0049] FIG. 2 is a perspective view of the exhaust 1. FIG. 3 is a plan view of the escape wheel 11 seen from a front side of the movement 101 (see FIG. 1). In Fig. 2, a balance wheel 52 is illustrated by a long dashed line at two points.
As illustrated in FIG. 2, the escapement 1 comprises the escapement wheel 11, a double plate 53 and the anchor 12.
The escape wheel 11 comprises an axle portion 13 and an escape wheel 14 which is mounted externally and fixedly on the axle portion 13.
The axle portion 13 has an axle portion body 16. In the axle portion body 16, a first tenon portion 17a is formed integrally in a final portion on a front side (upper side in Fig. 2) of movement 101 (see Fig. 1), a second tenon portion 17b being formed integrally in an end portion of a rear side (lower side in Fig. 2) of movement 101 (see Fig. 1). An axis diameter of the first tenon portion 17a and an axis diameter of the second tenon portion 17b are essentially identical to each other. The first tenon portion 17a is rotatably supported by a gear train (not shown), the second tenon portion 17b is rotatably supported by the main plate 102 described above (see Fig. 1).
In the axis portion body 16, an exhaust pinion 18 is integrally molded from a center substantially in the axial direction of the first tenon portion 17a. The exhaust pinion 18 is adapted to mesh with the gear of the second mobile 106 described above (see FIG. 1), the rotational force of the second mobile 106 being transmitted to the axle portion 13.
As illustrated in FIG. 3, the escape wheel 14 is an element formed of a metallic material or of a material having an orientation of the crystals such as a single crystal silicon, for example, and is formed by electroforming, a process called lithography galvanofurmung abformung (LIGA) in which includes an optical process such as photolithography, deep reactive ion etching (DRIE) or metal injection molding (MIM).
The escape wheel 14 has a portion forming a hub 20 essentially in the form of a ring which is forcibly mounted on the axle portion 13. In an outer peripheral portion of the hub portion 20, multiple spokes ( ten in the present embodiment) 21 which have a substantially oval shape so as to be elongated in a radial direction are formed integrally to have equal intervals in a circumferential direction. Next, the adjacent spokes 21 are in a state where basic side portions rather than essentially central portions in the radial direction are interconnected.
The spoke 21 is configured to include first multiple spokes 21a extending radially from the hub portion 20 and a second spoke 21b extending in the form of a fork from a distal end of the first spoke 21a. Then, the distal ends of the second radius 21b are interconnected. The first spoke 21a and the second spoke 21b form multiple openings 22 (ten). The escape wheel 14 is reduced in weight by forming the openings 22.
In addition, a tooth 23 terminating in a point in a direction of rotation (clockwise in Fig. 3) of the escape wheel 11 is integrally molded in a connecting portion 21c where the distal ends of the second radius 21b are interconnected.
The tooth 23 of the escape wheel 11 is configured so that a surface on the side of the direction of rotation of the escape wheel 11 is a contact surface 23a which comes into contact with a pallet d 45 (see Fig. 2, corresponding to a "first pallet" in the claims) and an outlet pallet 38 (see Fig. 2, corresponding to a "second pallet" in the claims) of the anchor 12 (to describe later).
The contact surface 23a of the tooth 23 of the escapement wheel 11 is tilted towards a side Q of the center of rotation of the escapement wheel 11.
As illustrated in FIG. 2, the double plate 53 is disposed in the balance 5 (to be described later) which moves in pivoting about a balance axis 51, is a component of the balance 5, and is a component of the escapement 1. The double-plate 53 is an element formed in a cylindrical shape, which is mounted externally and fixedly to the pendulum axis 51 so as to be disposed coaxially with an axis O. The axis O is the central axis of the axis of balance 51. The axis O is a pivot axis, namely the pivot axis of the balance 5 and the pivot axis of the double plate 53. Similarly to the portion of the escape wheel 14, the double-plate 53 is an element formed of a metallic material or of a material having an orientation of crystals such as a single crystal silicon, for example, and is formed by electroforming, the LIGA process in which an optical process like photolithography is integrated , the DRIE process or the MIM. A method of manufacturing the double plate 53 is not limited to the methods described above. For example, the double plate 53 can be formed by performing a mechanical treatment on the metallic material.
The double plate 53 comprises a large plate 54, formed in a position corresponding to the escapement wheel 11 in the axial direction of the pendulum axis, a small plate 55 formed on the other rear side (side lower of Fig. 2) of movement 101 (see Fig. 1) than the large plate 54, and a connecting portion 56, connecting the large plate 54 and the small plate 55. The large plate 54, the small plate 55 and a connecting portion 56 are formed integrally.
[0062] FIG. 4 is a perspective view of the double plate 53, FIG. 5 being a plan view of the double plate 53 and of the anchor 12. FIGS. 4 and 5 are views when viewed from the rear side of movement 101 (see Fig. 1).
As illustrated in FIG. 4, the large plate 54 is a disc-shaped element which has a hole 54a penetrating in the axial direction and a slot 54b formed so as to extend in the radial direction.
The hole 54a has a semi-circular shape which has a radially outer plane and has a radially inner arc considered in the axial direction. For example, a plate pin 57 is fixedly mounted by force on the hole 54a.
As illustrated in FIG. 5, the plate pin 57 is formed of a ruby, for example of semicircular shape which has a radially outer flat surface 57a and has a radially inner arched surface 57b considered from the axial direction. The plate pin 57 is arranged in the axial direction and projects towards the rear side (lower side of FIG. 2) of the movement 101 (see FIG. 1) from the large plate 54. In this way, as described in FIG . 2, the dowel pin 57 can come into contact with the anchor 12 (to be described later) in a position deviated from the balance pin 51 in the axial direction which is the other rear side of the movement 101 (see FIG. 1) that a position where the inlet pallet 45 and the outlet pallet 38 come into contact with the tooth 23 of the escape wheel 11.
The slot 54b has a U shape which has a radially outer opening considered from the axial direction. A pulse paddle 58 is inserted into the slot 54b from the outside in the radial direction and is fixed to the latter by an adhesive, for example.
The pulse palette 58 is formed of a ruby, for example, in the form of a rectangular plate. The impulse paddle 58 is disposed in the radial direction and a distal end portion protrudes radially outward from an outer peripheral surface of the large plate 54. A collision surface 58a which is flat in the radial direction is formed in the protruding portion of the impulse paddle 58. The tooth 23 (see Fig. 2) of the escape wheel 11 can collide with the collision surface 58a. In addition, a tilted surface 58b which is tilted radially inwards is formed in the projecting portion of the impulse paddle 58.
The small plate 55 is a disc-shaped element and has a diameter less than that of the large plate 54. On an outer peripheral surface 55a of the small plate 55, a crescent-shaped portion 55b having a shape of curved surface which returns radially inwards is formed in a position corresponding to the dowel pin 57. The crescent-shaped portion 55b plays a function of spacing zone which prevents the dart 41 of the anchor 12 from coming into contact with the small plate 55 when the anchor 12 (to be described later) and the plate pin 57 engage each other. In addition, the dart 41 of the anchor 12 can come into sliding contact with a partial region on the two circumferential sides on the crescent-shaped portion 55b inside the external peripheral surface 55a of the small plate 55.
As illustrated in FIG. 2, the anchor 12 comprises an anchor body 32 which has an essentially L-shape in a plan view by two anchor brackets 31a and 31b, an anchor pin 33 which pivotally supports the anchor body 32, and two pallets (inlet pallet 45 and outlet pallet 38).
The anchor pin 33 has a pin portion 34. Then, in the pin portion 34, a first tenon portion 35a is formed integrally in an end portion on the front side (upper side of Fig. 2) of movement 101 (see Fig. 1). A second tenon portion 35b is formed integrally in an end portion of the rear side (lower side of Fig. 2) of movement 101 (see Fig. 1). An axis diameter of the first tenon portion 35a and an axis diameter of the second tenon portion 35b are essentially identical to each other. The first tenon portion 35b is rotatably supported by an anchor bridge (not shown), the second tenon portion 35b is rotatably supported by the main plate 102 described above (see Fig. 1).
A flange portion 36 is disposed in a center essentially in the axial direction of the axle portion 34. The anchor body 32 is placed on the flange portion 36.
[0072] FIG. 6 is a perspective view of the anchor body 32.
As illustrated in FIG. 6, a hole 32a in which the axle portion 34 (see Fig. 2) of the anchor axle 33 can be inserted is formed in a connecting portion between the two anchor brackets 31a and 31b in the body anchor 32. By inserting the axle portion 34 into the hole 32a, the anchor body 32 is placed on the flange portion 36 (see FIG. 2) of the axle portion 34.
As illustrated in FIG. 2, a slot 37 is formed in a distal end of an anchor bracket 31a from the two anchor brackets 31a and 31b so that the side of the escape wheel 11 is open. The outlet pallet 38 is fixed to the slot 37 by an adhesive, for example.
The outlet pallet 38 is formed of a ruby, for example, in the form of a rectangular plate protrudes inwardly in the radial direction of the escape wheel 11 from the distal end of the bracket anchor 31a, and protrudes towards the escape wheel 11 so as to extend in the axial direction of the escape wheel 11. The outlet pallet 38 can disengage from the tooth 23 of the escape wheel 11 by the pivoting movement of the anchor 12.
A sliding surface 38a which cuts the circumferential direction of the escape wheel 11 and on which the tooth 23 of the escape wheel 11 can slide during the rotation of the escape wheel 11 is formed in one end distal of the outlet pallet 38. The tooth 23 of the escape wheel 11 is adapted to slide on the sliding surface 38a while being released from the outlet pallet 38, the escape wheel 11 being turned. In this way, the output pallet 38 moves outward in the radial direction of the escape wheel 11, the anchor 12 moving in pivoting about the anchor axis 33, by the adjustment of a central axis P of the anchor axis 33 to be a center of rotation.
In addition, another side of the proximal end than the sliding surface 38a of the outlet pallet 38 is an engagement surface 38b which engages the tooth 23 of the escape wheel 11.
[0078] FIG. 7 is a diagram illustrating an operation of the exhaust 1, and illustrates a state in which an engagement surface 45a of the input pallet 45 engages the contact surface 23a of the tooth part 23 of the escape wheel 11.
Here, being considered from the axial direction of the center of rotation Q of the escapement wheel 11, a straight line connecting the central axis P of the anchor axis 33 and a tooth tip of the tooth 23 of the escape wheel 11 is set to be a first straight line L1 and a straight line orthogonal to the first straight line L1 is set to be a second straight line L2. When the contact surface 23a of the escape wheel 11 engages the engagement surface 45a of the input pallet 45, the engagement surface 45a of the input pallet 45 is tilted relative to the second straight line L2 at a predetermined angle α in the direction of rotation of the escape wheel. The predetermined angle α is set to be approximately 11 ° to 16 °.
As described above, the engagement surface 45a of the input pallet 45 is tilted relative to the second straight line L2 according to the predetermined angle α in the direction of rotation of the escape wheel 11 Consequently, if the tooth 23 of the escapement wheel 11 and the input pallet 45 engage each other, a torque acts on the input pallet 45 so that the torque of the wheel d exhaust 11 pulls the input pallet 45 from the side of the exhaust wheel 11. In this way, it is possible to stabilize a state of engagement between the tooth 23 of the exhaust wheel 11 and the pallet entry 45. Therefore, for example, it is possible to prevent the engagement position of the entry pallet 45 with the tooth 23 of the escapement wheel 11 from being deflected therefrom due to the disturbance. Consequently, it is possible to prevent an abnormal operation in which the anchor 12 is caused to move in pivoting due to the disturbance, the small plate 55 and the dart 41 coming into mutual contact to interfere with the balance 5 ( see Fig. 2), the free vibration of the pendulum 5 being consequently prevented.
As illustrated in FIG. 6, the kite-shaped portions (lucane) 46 and 47 are arranged side by side across the width of the anchor bracket 31b, on one side with a distal end of the other anchor bracket 31b apart from the two anchor brackets 31a and 31b. The tilted surfaces 46a and 47a which are gradually tilted towards the proximal end side of the kite-shaped portions (lucane) 46 and 47 are respectively formed inwards from the outside in the width direction. the anchor bracket 31b, in the distal end portions of the kite-shaped portions (lucane) 46 and 47.
As illustrated in FIG. 5, a fork entry 39 from which the plate pin 57 can be released by the pivoting movement of the double plate 53 is formed inside the kite-shaped portions (lucane) 46 and 47.
For example, a convex portion (not shown) is integrally formed in a base portion 39a of the fork inlet 39, the sting 41 configuring the receptacle of the pallet 39 being fixed to the convex portion.
The dart 41 is configured to have a dart body 42 and a disc-shaped fixing portion 43 which is formed integrally in the proximal end of the dart body 42. An essentially cylindrical mounting portion 43a (see FIG. 6) which can be fixed on the convex portion of the base portion 39a is formed integrally in the fixing portion 43, for example. The dart 41 is fixedly mounted by force in a state where the fixing portion 43a is fixed on the convex portion. The dart 41 can adhere fixedly to the base portion 39a of the fork entry 39 by an adhesive, for example.
During the rotation of the double plate 53, the distal end of the dart 41 comes into sliding contact with a partial region on the two circumferential sides on the crescent-shaped portion 55b inside the outer peripheral surface 55a of the small plate 55. This can prevent the anchor from pivoting, even in a state where the plate pin 57 is detached from the fork entry.
As illustrated in FIG. 2, the anchor bracket 31b having the fork entry 39, a pallet link hole 44 is formed in the proximal end side of the fork entry 39. The entry pallet 45 fixedly adheres to the hole connecting the pallet 44 with an adhesive, for example. The entry pallet 45 is formed of a ruby for example, in the form of a square pillar and protrudes towards the side of the escape wheel 11 so as to extend along the central axis P of the axis anchor 33 from the distal end of the anchor bracket 31b. A lateral surface facing the opposite side of the anchor axis 33 of the entry pallet 45 is the engagement surface 45a which engages the tooth 23 of the escape wheel 11. The entry pallet 45 can disengage from tooth 23 of the escapement wheel 11 by the pivoting movement of the anchor 12.
A pair of limiting pins 61a and 61b is arranged on the opposite side of the escape wheel 11 on the anchor 12. The limiting pins 61a and 61b are erected from the main plate 102 (see Fig. 1), and are respectively disposed in a position greater than a position of the anchor 12. The pivoting movement of the anchor 12 causes the anchor brackets 31a and 31b to come into contact with the limiting pins 61a and 61b This regulates an amount of the pivoting movement of the anchor 12.
Cruise control and balance wheel
The balance 5 of the speed regulator 2 has the balance axis 51 which acts as a pivot, the balance wheel 52 which is mounted externally and fixedly to the balance axis 51, the double plate 53 described below. top and a spring (not shown). The two ends of the balance axle 51 are rotatably supported by a balance bridge (not shown) and the main plate 102. The escapement wheel 11 is turned and collides with the impulse paddle 58, providing thus the energy generated from the escape wheel 11 to the balance 5 as a rotational force. In addition, the tooth 23 of the escape wheel 11 slides on the sliding surface 38a and the anchor 12 pivots to collide with the plate pin 57, thus providing the energy generated from the wheel d 'escapement 11 to the balance 5 as a rotational force In addition, the energy of the escape wheel 11 is accumulated in the balance spring 5 as a spring force. Consequently, the rotational force generated by the energy supplied from the escape wheel 11 and the spring force allow the balance 5 to move in pivoting while executing a free vibration according to a predetermined cycle around the pivot axis O of the pendulum axis 51.
Action
As a result, an action of the exhaust 1, configured as described above, will be described with reference to the diagrams illustrating each of the operations of FIGS. 7 to 14. Figs. 11 and 13 are enlarged views of the double plate 53 and the fork entry 39.
Then, a case will be described sequentially in which the double plate 53 moves in pivoting around the pivot axis O in the anticlockwise direction (hereinafter the "anticlockwise direction d 'a watch' is called "CCW direction") in response to the free vibration of the pendulum 5, after which the double plate 53 moves in pivoting around the pivot axis O in a clockwise direction ( hereinafter "clockwise" is called "CW direction"). Furthermore, in a starting state of operation of the description, as illustrated in FIG. 7, the outlet pallet 38 is detached from the tooth 23 of the escape wheel 11, the engagement surface 45a of the inlet pallet 45 engaging the tooth 23 of the escape wheel 11. In addition, a lateral anchor bracket 31a now holding the output pallet 38 is in contact with the limiting pin 61b, the other lateral anchor bracket 31b holding the pallet 45 being detected by the limiting pin 61a.
As illustrated in FIG. 7, if the double plate 53 moves in pivoting in the CCW direction, the fork entry 39 of the anchor 12 engages the plate pin 57. At this time, the arcuate surface 57b of the plate pin 57 comes into contact with the inner surface of a lateral portion (right side in Fig. 7) in the form of a kite (stagger) 46. In this way, the rotational force of the double plate 53 (c.- i.e. the spring force of the balance spring 5, see Fig. 2) acts on the anchor 12.
Thereafter, as illustrated in FIG. 8, if the double plate 53 continues to pivot in the CCW direction, the arched surface 57b of the plate pin 57 compresses a portion in the form of a kite (stagger) 46. This causes the anchor 12, the input pallet 45 and the output pallet 38, which are held in the anchor 12 to move in pivoting around the central axis P of the anchor axis 33 in the direction CW. Here, the crescent-shaped portion 55b is formed in the small plate 55. In this way, during the engagement between the anchor 12 and the plate pin 57, the small plate 55 and the dart 41 of the anchor 12 are not in contact with each other. Consequently, without interference with the pivoting movement of the anchor 12, it is possible to efficiently transmit the rotational force of the double plate 53 to the anchor 12.
If the anchor 12 is pivoted, the input pallet 45 moves in a direction remote from the escape wheel 11. This results in the release of the input pallet 45 from the tooth 23 of the escape wheel 11. The inlet pallet 45 is detached from the tooth 23 of the escape wheel 11, the escape wheel 11 being turned in the direction CW.
In addition, if the escape wheel 11 rotates in the CW direction, the tooth 23 of the escape wheel 11 collides with the collision surface 58a of the impulse paddle 58. In this way, the energy generated from the escape wheel 11 is supplied to the double plate 53 (ie the pendulum 5, see Fig. 2) as a rotational force, the double plate 53 continuing to move pivotally in the CCW direction.
In addition, if the anchor 12 pivots, the outlet pallet 38 moves in a direction close to the escapement wheel 11. Then, as illustrated in FIG. 9, the outlet pallet 38 which moves in the vicinity of the escape wheel 11 comes into contact with the rotating escape wheel 11, the engagement surface 38b of the outlet pallet 38 engaging the tooth 23 of the escape wheel 11.
Here, similarly to the relationship described above between the contact surface 23a of the escape wheel 11 and the engagement surface 45a of the input pallet 45, the contact surface 23a of the escape wheel 11 and the engagement surface 38b of the outlet pallet 38 engage each other, the engagement surface 38b of the outlet pallet 38 being tilted relative to the second straight line L2 at a predetermined angle α in the direction of rotation of the escape wheel. In this way, if the tooth 23 of the escape wheel 11 engages the outlet pallet 38, a torque acts on the outlet pallet 38 so that the torque of the escape wheel 11 pulls the pallet outlet 38 in the side of the escapement wheel 11. In this way, it is possible to stabilize a state of engagement between the tooth 23 of the escapement wheel 11 and the outlet pallet 38. Consequently, by For example, it is possible to prevent the engagement position of the outlet pallet 38 with the tooth 23 of the escapement wheel 11 from being deflected therefrom due to the disturbance. Therefore, it is possible to prevent abnormal operation in which the anchor 12 is caused to pivotally move due to the disturbance, for example, the small plate 55 and the dart 41 coming into contact with each other to interfere with the balance 5 (see Fig. 2), the free vibration of balance 5 is therefore prevented.
In addition, at this time, the pivoting movement of the double plate 53 in the CCW direction causes the plate pin 57 and the fork input 39 of the anchor 12 to disengage each other. Here, the dart 41 of the anchor 12 is configured so that a surface on the side of the escape wheel 11 is in contact with the outer peripheral surface 55a of the retaining surface 55. This can prevent the anchor 12 to move pivotally, so as to move away from the limiting pin 61a, including in a state where the plate pin 57 is detached from the fork entry 39. Consequently, it is possible to '' prevent abnormal operation, called shaking, in which, when the double plate 53 moves in pivoting in the CCW direction, the plate pin 57 is detached from the fork entry 39, then the double plate 53 moves in pivoting in the CW direction and the plate pin 57 again engages the fork inlet 39, the plate pin 57 comes into contact with the external lateral surface (in this case, the external surface of a portion in the form of kite (lucane) lateral 46) of the fork entry 39, the movement of the plate pin 57 is prevented by the anchor 12, the pivoting movement of the balance 5 (see FIG. 2) being arrested.
In addition, as illustrated in FIG. 2, the exhaust 1 of this embodiment guarantees a quantity of engagement of the inlet pallet 45 and the outlet pallet 38 with the tooth 23 of the escapement wheel 11 so as to obtain a predetermined required quantity or higher. In this way, it is possible to prevent the abnormal operation according to so-called semi-shaking phenomenon. In an operating state where the inlet pallet 45 and the outlet pallet 38 are not supposed to disengage from the tooth 23 of the escapement wheel 11 in the operation provided at the origin of the escapement 1, for example example, in a state in which the plate pin 57 is not supposed to enter the fork entry 39, a strong disturbance causes the release of the entry pallet 45 and the exit pallet 38 from the tooth 23 of the escape wheel 11, the escape wheel 11 falling on the sliding surface 38a of the outlet pallet 38, for example. The impact is transmitted from the escape wheel 11 to the anchor 12 and the anchor 12 pivots. Consequently, the kite-shaped portions (lucane) 46 and 47 compress the plateau pin 57. In addition, the dart 41 (see FIG. 5) compresses the small plateau 55. Consequently, the balance 5 is compressed by the anchor 12 in the radial direction of the balance 5, the pivoting movement of the balance 5 being finally stopped.
The double plate 53 is configured so that the direction of the pivoting movement is reversed towards the CW direction after the amount of pivoting movement is maximized in the CCW direction. Then, as illustrated in FIG. 10, the fork entry 39 of the anchor 12 reengages the plate pin 57. At this point, as illustrated in FIG. 11, the arcuate surface 57b of the dowel pin 57 comes into contact with the interior surface of the other lateral portion in the form of a kite (stagger) 47 (left side in FIG. 11). This results in the action of the force of rotation of the double plate 53 (ie the spring force of the balance spring 5, see Fig. 2) on the anchor 12. Then, if the double- plate 53 still moves pivotally in the CW direction, as illustrated in FIG. 10, the anchor 12, and the input pallet 45 and the output pallet 38 which are held in the anchor 12, move in pivoting about the central axis P of the anchor axis 33 in the meaning CCW.
Thereafter, as illustrated in FIG. 12, if the anchor 12 pivots, the output pallet 38 moves in the direction opposite to the escape wheel 11. This causes the engagement surface 38b of the output pallet 38 to be released from the tooth 23 of the escape wheel 11. The escape wheel 11 moves in pivoting in the CW direction, the tooth 23 of the escape wheel 11 sliding on the sliding surface 38a.
Here, a vertical component of the sliding surface 38a in a vector F of the rotational force of the escape wheel 11 causes the pivoting movement of the anchor 12 about the central axis P of the anchor pin 33 in the CCW direction.
[0102] At that time, as illustrated in FIG. 13, the pivoting movement of the anchor 12 causes the inner surface of a lateral portion in the form of a kite (lucane) 46 (right side of FIG. 13) to collide with the arcuate surface 57b of the plateau pin 57, thereby applying the impact of the plateau pin 57. In other words, the tooth 23 of the escapement wheel 11 slides on the sliding surface 38a. In this way, a state in which the torque is transmitted from the dowel pin 57 to the anchor 12 as illustrated in FIG. 11 is switched to a state where the torque is transmitted from the anchor 12 to the plate pin 57 as illustrated in FIG. 13. As described above, the energy of the rotational force supplied by the escape wheel 11 is transmitted to the plate pin 57 (ie the balance 5, see Fig. 2) of the double plate 53 via anchor 12.
If the anchor 12 pivots in the CCW direction, the output pallet 38 moves in the direction opposite to the escape wheel 11. This causes the output pallet 38 to detach from the tooth 23 of the escape wheel 11, the latter continuing to rotate in the CW direction.
In addition, if the anchor 12 pivots in the CCW direction, the input pallet 45 moves in the direction opposite to the escape wheel 11. Next, as illustrated in FIG. 14, the entry pallet 45 which approaches the escape wheel 11 comes into contact with the escape wheel 11, the engagement surface 45a of the entry pallet 45 engaging the tooth 23 of the wheel d exhaust 11.
Here, as described above, the engagement surface 45a of the inlet pallet 45 is tilted relative to the second straight line L2 at a predetermined angle α in the direction of rotation of the escape wheel 11. Therefore, a torque acts on the input pallet 45 so that the torque of the escape wheel 11 pulls the input pallet 45 on the side of the exhaust wheel 11. In this way , it is possible to stabilize a state of engagement between the tooth 23 of the escapement wheel 11 and the input pallet 45. Therefore, for example, it is possible to prevent the engagement position of the pallet d entry 45 with the tooth 23 of the escape wheel 11 to be deflected therefrom due to the disturbance. Therefore, it is possible to prevent abnormal operation in which the anchor 12 is caused to pivotally move due to the disturbance, for example, the small plate 55 and the dart 41 coming into contact with each other to interfere with the balance 5 (see Fig. 2), the free vibration of balance 5 is therefore prevented.
In addition, at this time, the pivoting movement of the double plate 53 in the CW direction causes the mutual release of the plate pin 57 and the fork entry 39 of the anchor 12. Here , the dart 41 of the anchor 12 is configured so that a lateral surface opposite the escape wheel 11 is in contact with the outer peripheral surface 55a of the small plate 55. This can prevent the anchor 12 from move in a pivoting manner so as to be at a distance from the limiting pin 61b, including in a state where the plate pin 57 is detached from the fork entry 39. Consequently, it is possible to prevent abnormal operation , called shaking, in which, when the double plate 53 moves in pivoting in the CW direction, the plate pin 57 is detached from the fork entry 39, then the double plate 53 moves in pivoting in the direction CCW and pla ankle plate 57 again engages the fork inlet 39, the plate pin 57 coming into contact with the external lateral surface (in this case, the external surface of the other portion in the form of a lateral kite 47) from the fork entry 39, the movement of the plate pin 57 is prevented by the anchor 12, the pivoting movement of the balance 5 (see FIG. 2) being arrested.
In addition, the exhaust 1 of this embodiment guarantees a quantity of engagement of the input pallet 45 and the output pallet 38 with the tooth 23 of the escape wheel 11, so as to obtain a predetermined or greater required quantity. In this way, it is possible to prevent the abnormal operation according to so-called semi-shaking phenomenon. In an operating state where the inlet pallet 45 and the outlet pallet 38 are not supposed to disengage from the tooth 23 of the escapement wheel 11 in the operation provided at the origin of the escapement 1, for example example, in a state in which the plate pin 57 is not supposed to enter the fork entry 39, a strong disturbance causes the release of the entry pallet 45 and the exit pallet 38 from the tooth 23 of the escape wheel 11, the escape wheel 11 falling on the sliding surface 38a of the outlet pallet 38, for example. The impact is transmitted from the escape wheel 11 to the anchor 12 and the anchor 12 pivots. Consequently, the kite-shaped portions (lucane) 46 and 47 compress the plateau pin 57. In addition, the dart 41 (see FIG. 5) compresses the small plateau 55. Consequently, the balance 5 is compressed by the anchor 12 in the radial direction of the balance 5, the pivoting movement of the balance 5 being finally stopped.
The double plate 53 is configured so that the direction of the pivoting movement is reversed in the CCW direction after the amount of pivoting movement is maximized in the CW direction (see Fig. 7). Then, the operation described above is repeated. In this way, the tooth 23 of the escape wheel 11 is released repeatedly and alternately from the inlet pallet 45 and the outlet pallet 38. This allows the escape wheel 11 to rotate in the CW direction. always at a constant speed.
According to the first embodiment, the anchor 12 comprises two pallets of the input pallet 45 and the output pallet 38. Therefore, compared to the related art comprising three pallets, a pallet can be reduced and a space for fixing the reduced pallet can be reduced. In addition, compared to the related art, the pallet and the exhaust pinion 18 must not come into contact with each other. Therefore, it is possible to reduce the diameter of the exhaust pinion 18. This makes it possible to reduce the dimensions and the weight of the anchor 12 and of the escape wheel 11. Consequently, it is possible to reduce the resistance to the friction due to the viscosity and the resistance to friction due to the mass when the anchor 12 and the escape wheel 11 move in pivoting. In addition, the reduced weight of the anchor 12 and the escape wheel 11 decreases the moment of inertia compared to the related art. Consequently, the anchor 12 can move in pivoting and quickly. In this way, an impact domain is widened when the anchor 12 collides with the dowel pin 57 and the escape wheel 11 collides with the impulse paddle 58. Consequently, it is possible to transmit energy efficiently. According to the description above, it is possible to improve the efficiency of the energy transmission from the escape wheel 11 to the balance 5 due to the reduced size and the reduced weight of the anchor 12 and the escape wheel 11.
In addition, the double plate 53 includes the plate pin 57 which comes into contact with the anchor 12 in response to the pivoting movement of the double plate 53 and causes the pivoting movement of the anchor 12 around the anchor pin 33, and the impulse paddle 58 which can come into contact with the tooth 23 of the escapement wheel 11. So, for example, including in the escapement requiring lubrication of the paddles and the tooth of the escape wheel, it is possible to suppress the diffusion of oil towards the contact portion between the dowel pin 57 and the anchor 12. Consequently, it is possible to ensure stable operation of the regulator speed 2, including exhaust 1 and balance 5 by preventing oil adhesion or an increase in viscosity resistance caused by deterioration of the adherent oil. It is therefore possible to prevent deterioration of the adjustment accuracy.
In addition, without depending on the position of the plate pin 57, it is possible to adjust a desired position of the impulse paddle 58, a desired outside diameter of the escape wheel 11 and a separation distance desired between the balance axis 51 and the center Q of rotation of the escapement wheel 11. In this way, it is possible to adjust a desired impact area when the tooth 23 of the escapement wheel 11 and the impulse paddle 58 collide with each other. Consequently, it is possible to adjust a desired balance between the efficiency of the transmission of energy from the exhaust 1 and the adjustment precision.
In addition, when the double plate 53 moves in pivoting anticlockwise (CCW), the input pallet 45 and the escape wheel 11 are released mutually, the tooth 23 of the escape wheel 11 and the impulse paddle 58 coming into mutual contact. Consequently, it is possible to supply the energy by directly applying the impact to the impulse paddle 58 from the escape wheel 11. In addition, when the double plate 53 is pivotally moving in the direction clockwise (CW), the output paddle 38 and the escapement wheel 11 are mutually released, the tooth 23 of the escapement wheel 11 being caused to slide on the sliding surface 38a. Consequently, it is possible to cause the anchor 12 to pivot about the anchor axis 33 by moving the output pallet 38. Consequently, it is possible to supply the energy by applying the impact to the plate pin 57 from the escape wheel 11 via the anchor 12.
In addition, the present embodiment is provided with the small plate 55 with which the dart 41 comes into sliding contact. As a result, it is possible to prevent the anchor 12 from pivoting, even in a state where the plate pin 57 is detached from the fork inlet 39. Therefore, it is possible to prevent a abnormal operation, called shaking, in which the plate pin 57 is detached from the fork input 39 after the plate pin 57 comes into contact with the outer surface of the fork input 39, the movement of the pin of plate 57 being hampered by the anchor 12 and the pivoting movement of the pendulum 5 being stopped.
In addition, the engagement surface 45a of the inlet pallet 45 and the engagement surface 38b of the outlet pallet 38 are tilted relative to the second straight line L2 at an angle α predetermined in the direction of rotation of the escapement wheel 11. Consequently, if the tooth 23 of the escapement wheel 11 engages the inlet pallet 45 and the outlet pallet 38, a torque acts on the inlet pallet 45 and the respective output paddle 38 so that the torque of the escape wheel 11 pulls the respective paddles on the side of the escape wheel 11. In this way, it is possible to stabilize a state of engagement between the tooth 23 of the escape wheel 11 and the input pallet 45, and the output pallet 38. So, for example, it is possible to prevent the engagement position of the input pallet 45 and the output pallet 38 with the tooth 23 of the escape wheel 11 to be d avoided due to disturbance. Consequently, it is possible to prevent an abnormal operation in which the anchor 12 is caused to move in pivoting due to the disturbance, the small plate 55 and the dart 41 coming mutually in contact to interfere with the balance 5, the free vibration of the pendulum 5 is therefore prevented.
In addition, the present embodiment is provided with the exhaust 1 described above. Therefore, it is possible to provide the high performance watch movement 101 and the high performance watch 100 which can improve the efficiency of the power transmission and whose setting precision is excellent.
Second embodiment
[0116] FIG. 15 is a perspective view of the exhaust 201 according to a second embodiment, FIG. 16 being a plan view of an anchor 212 according to the second embodiment.
Thereafter, the exhaust 201 according to the second embodiment will be described.
The exhaust 1 according to the first embodiment is configured so that the anchor 12 consists of the anchor body 32 (see Fig. 2).
On the contrary, the escapement 201 according to the second embodiment is different from that of the first embodiment in that the anchor 212 is formed from a first anchor body 231 and from a second body d anchor 241 as illustrated in FIG. 15. Hereinafter, the description of configuration elements which are identical to those of the first embodiment will be omitted, only different elements being described.
As illustrated in FIG. 16, the anchor 212 comprises a first anchor body 231 of essentially L shape in a plan view by two anchor brackets 231a and 231b, a second anchor body 241 of essentially L shape in a plan view plane by two anchor brackets 241a and 241b, and an anchor pin 33 pivotally supporting the first anchor body 231 and the second anchor body 241.
As illustrated in FIG. 15, the first anchor body 231 and the second anchor body 241 are arranged so as to overlap each other in the axial direction of the anchor axis 33 and of the pendulum axis 51. Specifically, the first anchor body 231 is disposed in a position corresponding to the escape wheel 11 in the axial direction, the second anchor body 241 being disposed in a position corresponding to a portion of engagement with the plate pin 57 of the double plate 53, which is the other rear side (lower side of FIG. 15) of the movement 101 (see FIG. 1) than the first anchor body 231.
As illustrated in FIG. 16, in the distal ends of the two anchor brackets 231a and 231b which form the first anchor body 231, slots 237a and 237b are formed respectively, so that the side of the escape wheel 11 (see Fig. 15) is open. An outlet pallet 238 is fixed to the slot 237a of an anchor bracket 231a, an inlet pallet 245 is fixed to the slot 237b of the other lateral anchor bracket 231b, respectively by means of adhesives, for example. The output pallet 238 and the input pallet 245 are respectively in the form of a square pillar and are respectively in a state of protrusion towards the escape wheel 11 from the distal ends of the anchor brackets 231a and 231b. In this case, the first anchor body 231 is disposed in a position corresponding to the escape wheel 11 in the axial direction. Consequently, the output pallet 238 and the output pallet 245 can disengage respectively from the input portion 23 of the escape wheel 11, including without being respectively caused to protrude in the axial direction.
As illustrated in FIG. 15, a lateral anchor bracket 241a between the two anchor brackets 241a and 241b which form the second anchor body 241 is disposed between the limiting pins 61a and 61b and comes into contact with the limiting pins 61a and 61b by the pivoting movement of the anchor 212. This regulates the amount of pivoting movement of the anchor 212.
In addition, as illustrated in FIG. 16, the fork inlet 39 is molded integrally in the distal end of the other lateral anchor bracket 241b.
According to the second embodiment, the first anchor body 231 which holds the inlet pallet 245 and the outlet pallet 238, and the second anchor body 241 which can come into contact with the plateau pin 57 are arranged so as to overlap each other in the axial direction of the pendulum axis 51. In this way, it is possible to arrange the first anchor body 231 in the position corresponding to the tooth 23 of the wheel d exhaust 11 and to arrange the second anchor body 241 in the position corresponding to the plate pin 57 in the axial direction. This can prevent the inlet pallet 245 and the outlet pallet 238 held by the first anchor body 231 from being extended in the axial direction. Therefore, it is possible to decrease the weight of the input pallet 245 and the output pallet 238, and it is possible to decrease the bending movement acting on the input pallet 245 and the output pallet 238 when the inlet pallet 245 and the outlet pallet 238 come into contact with the tooth 23 of the escape wheel 11. Therefore, it is possible to provide the excellent exhaust 201 which can realize the reduced weight and the improved durability .
Third embodiment
[0126] FIG. 17 is a perspective view of an exhaust 301 according to a third embodiment, FIG. 18 being a plan view of a second escape wheel 315 according to the third embodiment.
Thereafter, the exhaust 301 according to the third embodiment will be described.
The exhaust 1 according to I first embodiment is configured so that the escape wheel 11 consists of an escape wheel 14 (see Fig. 2).
On the contrary, the exhaust 301 according to the third embodiment is different from that of the first embodiment in that an escape wheel 311 is formed of a first escape wheel 314 and a second escape wheel 315 as illustrated in FIG. 17. Below, the description of configuration elements which are identical to those of the first embodiment will be omitted, only different elements being described.
As illustrated in FIG. 17, the escape wheel 311 comprises the first escape wheel 314, the second escape wheel 315 which is arranged so as to be covered by the first escape wheel 314 in the axial direction and which is the other rear side (lower side of Fig. 17) of movement 101 (see Fig. 1) than the first escape wheel 314.
The first escape wheel 314 has a first tooth 323. The first escape wheel 314 in the third embodiment has a shape which is identical to that of the escape wheel 14 (see Fig. 3) in the first embodiment and its description will therefore be omitted.
As illustrated in FIG. 18, the second escape wheel 315 is an element formed of a metallic material or of a material having an orientation of the crystals such as a single crystal silicon, for example, and is formed by electroforming, LIGA process in which an optical process as photolithography is integrated, DRIE or MIM. A method of manufacturing the second escape wheel 315 is not limited to the methods described above. For example, the second escape wheel 315 can be formed by performing mechanical processing of the metallic material. The second escape wheel 315 has a central portion essentially in the form of a ring 325 which is inserted into the axle portion 13 (see Fig. 17). A hole 325a mounted on the axis portion 13 is formed in the central portion 325.
Multiple spokes (ten in this embodiment) 326 extending in the radial direction are molded integrally and radially in an outer peripheral portion of the central portion 325. A substantially annular rim portion 327 is integrally molded in a distal end of the spoke 326. In this way, multiple openings (ten) 328 are formed in the circumferential direction in the second escape wheel 315.
In addition, in the outer peripheral portion of the rim portion 27, multiple second teeth (ten in the present embodiment) 329 which are formed in a special hook shape in a plan view are formed so to extend radially outwards. An outlet pallet 338 (see Fig. 17) from the anchor 12 is configured to come into contact with the distal end of the second multiple teeth 329.
A pulse surface 329a is formed in the distal end of the second tooth 329. The pulse surface 329a is formed flat so as to cut an extension direction of the second tooth 329. As illustrated by Fig. 17, the tooth surface 329a is configured so that in response to the rotation of the escape wheel 311, the second tooth 329 of the escape wheel 311 slides on a sliding surface 338a of a pallet 338 and the output pallet 338 then slides over it.
The second escape wheel 315 is forcibly mounted on the axle portion 13, for example, in a state where its phases are mutually aligned so that the second tooth 329 of the second escape wheel 315 is located between the first two adjacent teeth 323 of the first escape wheel 314. The second escape wheel 315 can adhere firmly to the axle portion 13 by means of an adhesive, for example.
The output pallet 338 is formed of a ruby, for example in the form of a square pillar, and protrudes towards the escape wheel 11 from the distal end of the anchor bracket 31a. In this case, the second escape wheel 315 is placed in a position corresponding to the anchor 12 in the axial direction. Consequently, the output pallet 338 can disengage from the second input portion 329 of the second escape wheel 315, including without being caused to protrude in the axial direction.
According to the third embodiment, the first escape wheel 314 and the second escape wheel 315 are arranged so as to overlap each other in the axial direction, the impulse paddle 58 being able to come into contact with the first tooth 323 of the first escapement wheel 314, and the output pallet 338 being able to disengage from the second tooth 329 of the second escape wheel 315. It is therefore possible to arrange the impulse pallet 58 in the position corresponding to the first tooth 323 of the first escape wheel 314 and to arrange the output pallet 338 in the position corresponding to the second tooth 329 of the second escape wheel 315 in the axial direction. This can prevent the impulse paddle 58 and the output paddle 338 from being extended in the axial direction. Consequently, it is possible to reduce the weight of the impulse paddle 58 and the output paddle 338, and it is possible to reduce the bending moment acting on the impulse paddle 58 when the impulse paddle 58 comes into contact with the first tooth 323 of the escapement wheel 311, and the bending moment acting on the outlet pallet 338 when the outlet pallet 338 comes into contact with the second tooth 329 of the escapement wheel 311.
In addition, the second escape wheel 315 is further reduced in diameter compared to the first the escape wheel 314. In this way, it is possible to increase the torque generated in the anchor 12 relative to the torque generated in the second escape wheel 315. In addition, the reduced weight of the input pallet 45 and the output pallet 338 can reduce the moment of inertia of the anchor 12. Consequently, when the Energy is supplied by applying the impact to the plate pin 57 from the escape wheel 311 via the anchor 12, it is possible to further improve the efficiency of the energy transmission.
In addition, the first tooth 323 of the first escapement wheel 314 and the second tooth 329 of the second escapement wheel 315 can be adapted to have different shapes which are suitable for the respective teeth. Consequently, it is possible to improve the resistance of the first tooth 323 of the first escape wheel 314 and of the second tooth 329 of the second escape wheel 315.
In addition, the first tooth 323 of the first escapement wheel 314 with which the impulse paddle 58 comes into contact and the second tooth 329 of the second escapement wheel 315 from which the outlet paddle 338 is released are arranged in positions respectively mutually deflected in the axial direction. So, for example, even if the output pallet 338 and the second tooth 329 of the second escapement wheel 315 are lubricated, it is possible to reliably suppress the diffusion of oil towards the contact portion between the pin plate 57 and anchor 12, and it is also possible to reliably suppress the diffusion of oil towards the impulse paddle 58.
In addition, the second tooth 329 slides on the sliding surface 338a of the output pallet 338, after which the output pallet 338 continues to slide on the impulse surface 329a of the second tooth 329. In this way , it is possible to apply a significant torque to the balance 5 via the anchor 12. Consequently, the energy transmitted to the balance 5 can be further improved by the escape wheel 311 which has the first tooth 323 and the second tooth 329 which can apply a direct impact to the impulse palette 58.
Modifying example of the third embodiment
[0143] FIG. 19 is a perspective view of the exhaust 301 according to an amending example of the third embodiment.
Thereafter, the exhaust 301 according to the example of modification of the third embodiment will be described.
In the exhaust 301 according to the third embodiment, the escape wheel 11 comprises the first escape wheel 314 and the second escape wheel 315. The first tooth 323 which emerges from the pallet inlet 45 is formed in the first escape wheel 314 and the second tooth 329 which emerges from the outlet pallet 338 is formed in the second escape wheel 315.
On the contrary, as in the exhaust 301 according to the example of modification of the third embodiment illustrated in FIG. 19, the escape wheel 11 can comprise an escape wheel 314A having the first tooth 323, the second tooth 329 being able to be formed integrally with the escape wheel 314A. Hereinafter, the description of configuration elements which are identical to those of the third embodiment will be omitted, only different elements being described.
The escape wheel 314A has a first tooth 323 and a second tooth 329. The second tooth 329 has a special hook shape in a plan view and has the shape of a pillar extending towards the rear side (lower side in Fig. 19) of movement 101 (see Fig. 1) in the axial direction of the escapement wheel 11 (ie the axial direction of the pendulum axis 51). The second tooth 329 is arranged in a deflected position in the other direction CW relative to the first tooth 323 which is the other radially inner side of the end of the first tooth 323, and is configured so that the outlet pallet 338 of the anchor 12 comes into contact with it. Similarly to the third embodiment, the pulse surface 329a is formed in the distal end of the second tooth 329. An operating effect of the pulse surface 329a is identical to that of the third embodiment; its description will therefore be omitted.
According to the modifying example of the third embodiment, the second tooth 329 extends in the axial direction. Therefore, compared to a case where tooth 329 is formed as a gear, it is possible to decrease the weight. This can reduce the moment of inertia of the escape wheel 311. It is therefore possible to improve the efficiency of the energy transmission from the escape wheel 311 to the balance 5.
In addition, it is possible to easily adjust the separation distance of the second tooth 329 by adjusting the thickness of the second tooth 329. It is therefore possible to easily ensure the spacing between the output pallet 338 and the second tooth 329. Consequently, it is possible to provide the escape wheel 311, the design flexibility of which is excellent.
Fourth embodiment
[0150] FIG. 20 is a perspective view of a double plate 453 configuring an exhaust 401 according to a fourth embodiment.
The exhaust 1 according to the first embodiment is configured so that the double plate 53 includes the large plate 54, the small plate 55 and the connecting portion 56, the plate pin 57 and the pallet impulse 58 being fixed to the large plate 54 (see Fig. 4).
On the contrary, the exhaust 401 according to the fourth embodiment is different from that of the first embodiment in that, as illustrated in FIG. 20, the double plate 453 comprises a first double plate body 453a and a second double plate body 453b, the plate pin 57 being fixed to the first double plate body 453a and the impulse paddle 58 being fixed to the second double-plate body 453b. Hereinafter, the description of configuration elements which are identical to those of the first embodiment will be omitted, only different elements being described.
The double plate 453 comprises the first double plate body 453a and the second double plate body 453b which is arranged so as to be covered by the first double plate body 453a in the axial direction of the balance 51 axis, on the other side of balance wheel 52 relative to the first double-plate body 453a.
The first double-plate body 453a comprises a first large plate 454a, the small plate 55 which is formed on the other rear side (lower side of FIG. 20) of the movement 101 (see FIG. 1) by relative to the first large plate 454a, and the connecting portion 56 which connects the first large plate 454a and the small plate 55.
The hole 54a for penetration in the axial direction formed in the first rear rib of conical face 454a, the plate pin 57 being fixedly mounted by force thereon, for example.
The second double-plate body 453b is a disc-shaped element which entirely serves as a second large plate 454b. The slot 54b which extends in the axial direction is formed in the second rear conical rib 454b. The impulse paddle 58 is inserted into the slot 54b from the outside in the radial direction and is fixed to the latter by an adhesive, for example. The first tapered rear rib 454a and the second tapered rear rib 454b form a tapered rear rib 454 of the double plate 453.
According to the fourth embodiment, the double plate comprises the first double plate body 453a which holds the plate pin 57 and the second double plate body 453b which holds the impulse paddle 58. It is therefore possible to distribute the stress when the plate pin 57 comes into contact with the anchor 12 and the stress when the impulse paddle 58 comes into contact with the tooth 23 of the escape wheel 11, respectively at the level of the first double tray body 453a and the second double tray body 453b. In addition, for example, even if the plate pin 57 and the impulse paddle 58 are fixed to the double plate 453 by force and, in addition, the double plate 453 is fixed to the balance pin 51 by force, it is possible to distribute the stress generated during the force mounting at the level of the first double-plate body 453a and of the second double-plate body 453b. Consequently, it is possible to ensure the rigidity of the double plate 453 and it is possible to provide an exhaust 401 whose durability is excellent.
The technical scope of the present invention is not limited to the embodiments described above, but can also be modified in different ways without departing from the spirit of the present invention.
The shape or material of the escape wheels 11 and 311, the anchors 12 and 212, the double plates 53 and 453, the input pallets 45 and 245, the output pallets 38, 238 and 338, first ellipses 57 and second ellipses 58 are not limited to those of the respective embodiments.
In addition, the methods for fixing the input pallets 45 and 245, the output pallets 38, 238 and 338, the plate pin 57 and the impulse pallet 58 are not limited to those of respective embodiments.
[0161] Furthermore, in the respective embodiments, the first pallet in the claims has been described as the input pallets 45 and 245, the second pallet in the claims having been described as the output pallets 38, 238 and 338. However, the first pallet in the claims can represent the output pallets 38, 238 and 338 and the second pallet in the claims can represent the input pallets 45 and 245.
In addition, without departing from the scope defined by the independent claim, it is possible to appropriately replace the configuration elements in the embodiments described above by known configuration elements.

权利要求:
Claims (12)
[1]
1. Escape for a watch movement, comprising:an escape wheel (11; 311);a double plate (53; 453) intended to equip a balance (5) and to pivot on a pivot axis (O) of the double plate; andan anchor (12; 212) able to pivot on an anchor axis (33),wherein the double plate (53; 453) comprises a plate pin (57) capable of coming into contact with the anchor (12; 212) in response to a pivoting movement of the double plate (53; 453) and causing the anchor (12; 212) to pivot on the anchor axis (33), and a pulse paddle (58) capable of coming into contact with a tooth (23; 323, 329) of the wheel exhaust (11; 311), andwherein the anchor (12; 212) comprises two pallets (38, 45; 238, 245; 338).
[2]
2. Exhaust according to claim 1,in which the two pallets of the anchor, called first pallet (45; 245) and second pallet (38; 238; 338), can be released from the tooth (23; 323, 329) of the escape wheel (11 ; 311) in response to a pivoting movement of the anchor (12; 212) and cause rotation and stopping of the escape wheel (11; 311),wherein a distal end of the second pallet (38; 238; 338) includes a sliding surface (38a; 338a) which intersects a circumferential direction of the escape wheel (11; 311) and on which the tooth (23; 323, 329) of the escape wheel (11; 311) can slide during the rotation of the escape wheel (11; 311),in which, when the double plate (53; 453) pivots in one direction on the pivot axis (O), the first pallet (45; 245) and the escape wheel (11; 311) are released one from the other, the tooth (23; 323, 329) of the escape wheel (11; 311) and the impulse paddle (58) coming into contact with each other, andin which, when the double plate (53; 453) pivots in the other direction, the second pallet (38; 238; 338) and the escape wheel (11; 311) are released from one another , the tooth (23; 323, 329) of the escape wheel (11; 311) sliding on the sliding surface (38a; 338a).
[3]
3. Exhaust according to claim 2,wherein the anchor (12; 212) comprises a first anchor body (231) and a second anchor body (241) which follow one another in the pivoting direction (O), the first anchor body (231 ) holding the first pallet (45; 245) and the second pallet (38; 238; 338), the second anchor body (241) being able to come into contact with the plate pin (57).
[4]
4. Exhaust according to claim 2 or 3,in which the escape wheel (311) comprises a first escape wheel (314) and a second escape wheel (315) which follow one another in the direction of the pivot axis (O),wherein the tooth (323, 329) of the escape wheel (311) comprises a first tooth (323) which is formed in the first escape wheel (314) and a second tooth (329) which is formed in the second escape wheel (315), andwherein at least the impulse paddle (58) can contact the first tooth (323), and at least the second paddle (38; 238; 338) can disengage from the second tooth (329).
[5]
5. Exhaust according to claim 2 or 3,in which the tooth (323, 329) of the escape wheel (311) has a first tooth (323) and a second tooth (329) which extends in the direction of the pivot axis (O), andwherein at least the impulse paddle (58) can come into contact with the first tooth (323), and at least the second paddle (38; 238; 338) can disengage from the second tooth (329).
[6]
6. Exhaust according to claim 4,wherein the second tooth (329) has a pulse surface (329a) on which the second paddle (38; 238; 338) slides after the second tooth (329) of the escape wheel (11; 311) has slid on the sliding surface (38a; 338a) of the second pallet (38; 238; 338) in response to the rotation of the escape wheel (11; 311).
[7]
7. Exhaust according to claim 5,wherein the second tooth (329) has a pulse surface (329a) on which the second paddle (38; 238; 338) slides after the second tooth (329) of the escape wheel (11; 311) has slid on the sliding surface (38a; 338a) of the second pallet (38; 238; 338) in response to the rotation of the escape wheel (11; 311).
[8]
8. Exhaust according to one of claims 1 to 3,in which the double plate (53; 453) comprises a first double plate body (453a) and a second double plate body (453b) which follow one another in the direction of the pivot axis (O), the first double-plate body (453a) holding the plate pin (57), the second double-plate body (453b) holding the impulse paddle (58).
[9]
9. Exhaust according to one of claims 1 to 3,wherein the anchor (12; 212) comprises a fork entry (39) whose inner surface can come into contact with the plate pin (57), and a stinger (41) which extends from an inner side of the fork entry (39) in the direction of the double plate (53; 453), andwherein the double plate (53; 453) comprises a small plate (55) with which the dart (41) comes into sliding contact.
[10]
10. Exhaust according to one of claims 1 to 3,wherein the tooth (23; 323, 329) of the escape wheel (11; 311) has a contact surface (23a) which comes into contact with each pallet (38, 45; 238, 245; 338) of the 'anchor,wherein each pallet (38, 45; 238, 245; 338) of the anchor has an engagement surface (38b, 45a) which engages the contact surface (23a) of the escape wheel (11; 311) ,in which, seen from the direction of the axis of rotation of the escape wheel (11; 311), a straight line connecting a central axis of the anchor axis (33) with a tooth tip of the tooth (23; 323, 329) of the escape wheel (11; 311) is chosen to be a first straight line (L1) and a straight line orthogonal to the first straight line is chosen to be a second straight line (L2) , andin which, when the contact surface (23a) of the escape wheel (11; 311) and the engagement surface (38b, 45a) of any pallet of the anchor engage one 'other, the engagement surface (38b, 45a) of the pallet is inclined relative to the second straight line (L2) by a predetermined angle (α) in a direction of rotation of the escape wheel (11; 311).
[11]
11. Watch movement, comprising an escapement according to claim 1.
[12]
12. Timepiece, comprising a timepiece movement according to claim 11.

类似技术:

---

公开号 | 公开日 | 专利标题

---

CH708390B1|2020-04-30|Escapement comprising an anchor, timepiece movement and timepiece comprising such an escapement.

---

EP2998800A2|2016-03-23|Timepiece component with flexible pivot

---

EP1772783B1|2010-06-16|Watch movement with constant-force device

---

EP2407830B1|2014-11-05|Timepiece

---

EP3029530B1|2019-08-14|Tourbillon mechanism

---

EP1445668A1|2004-08-11|Oscillating weight

---

CH708525B1|2018-12-14|Mechanism for stabilizing the operation of the sprung balance, watch movement and mechanical watch.

---

EP3182213B1|2018-09-12|Mechanism for adjusting an average speed in a clock movement and clock movement

---

FR2791110A1|2000-09-22|DEVICE FOR DAMPING SWING MASSES WITH FORCED BEARING

---

CH708526A2|2015-03-13|Constant force device, and mechanical watch movement.

---

EP3070537A1|2016-09-21|Time base comprising an escapement with direct pulse and constant force

---

CH709329A2|2015-09-15|Exhaust, room and clockwork timepiece.

---

EP1640821A1|2006-03-29|Watch movement with a plurality of balances

---

EP3040783B1|2017-07-26|Sub-assembly for a mechanism for adjusting a speed in a clock movement and such a mechanism

---

CH709328A2|2015-09-15|Exhaust, timepiece movement and timepiece.

---

EP2533109A1|2012-12-12|Mechanism preventing rate variations due to gravitation on an adjusting device with a spiral balance and timepiece equipped with such an improvement

---

EP1562086A1|2005-08-10|Power reserve indicator mechanism

---

EP2444860A1|2012-04-25|Regulating mechanism for aTimepiece

---

CH710863A2|2016-09-15|frequency stabilization mechanism, movement and mechanical timepiece.

---

CH710108B1|2020-03-31|Constant force mechanism, movement and timepiece.

---

EP3382468B1|2020-01-15|Movement with extension of running reserve

---

EP3182214A1|2017-06-21|Mechanical oscillator for timepiece, adjustment mechanism comprising said mechanical oscillator, and clock movement

---

CH717089A2|2021-07-30|Exhaust and regulator assembly, timepiece movement and timepiece.

---

CH717216A2|2021-09-15|Spiral spring for timepiece.

---

WO2019179824A1|2019-09-26|Chronograph for a timepiece

同族专利:

---

公开号 | 公开日

---

CN104345627A|2015-02-11|

---

JP2015025719A|2015-02-05|

---

JP6210535B2|2017-10-11|

---

US20150029827A1|2015-01-29|

---

CH708390A2|2015-01-30|

---

CN104345627B|2018-03-09|

---

US9098067B2|2015-08-04|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

FR567914A|1922-10-25|1924-03-12|watch movement escapement|

---

US3267742A|1964-07-06|1966-08-23|Mastercrafters Clock Corp|Escapement noise reducing means|

---

US3538705A|1968-11-07|1970-11-10|Hamilton Watch Co|Escapement|

---

JPS496113Y1|1969-12-09|1974-02-13|

---

CH1082672A4|1972-07-19|1975-03-14|

---

CH1020375A4|1975-08-05|1977-06-30|

---

EP0018796B1|1979-04-30|1984-11-07|George Daniels|Watches, clocks and chronometers and escapements therefor|

---

TWI461865B|2006-06-23|2014-11-21|Omega Sa|"sprung balance regulating system for a mechanical timepiece movement and timepiece having such a system|

---

EP1914605A1|2006-10-19|2008-04-23|Patek, Philippe SA|Lever escapement|

---

AT475913T|2007-05-30|2010-08-15|Omega Sa|ANCHORING FOR WATCHES|

---

JP5462006B2|2009-02-17|2014-04-02|セイコーインスツル株式会社|Escape governor, mechanical timepiece, and method of manufacturing ankle body|

---

JP5366318B2|2009-09-14|2013-12-11|セイコーインスツル株式会社|Detent escapement and method of manufacturing detent escapement operating lever|

---

IT1396734B1|2009-11-25|2012-12-14|Ferrara|ESCAPEMENT FOR HIGH PERFORMANCE CLOCKS.|

---

EP2400351B1|2010-06-22|2013-09-25|Omega SA|Single-piece mobile element for a clock piece|EP3321747B1|2015-08-25|2020-09-30|Citizen Watch Co., Ltd.|Watch escapement|

---

EP3179315B1|2015-12-11|2019-03-27|ETA SA Manufacture Horlogère Suisse|Stud support with secure mounting|

---

CN106707718B|2017-03-01|2019-01-29|谭泽华|Clock and watch split axle impacts release catch|

---

JP6901876B2|2017-03-13|2021-07-14|セイコーインスツル株式会社|Escapement, watch movements and watches|

---

FR3074589A1|2017-12-02|2019-06-07|Jean Pommier|ANCHOR LOST HORLOGER EXHAUST|

---

EP3901707A4|2020-04-23|2021-10-27|Eta Sa Mft Horlogere Suisse|Escapement mechanism for a timepiece|

法律状态:

优先权:

---

申请号 | 申请日 | 专利标题

---

JP2013154978A|JP6210535B2|2013-07-25|2013-07-25|Escapement, watch movement and watch|

---