JP5882089B2 - Temperature compensated balance, watch movement and watch - Google Patents

Description

  The present invention relates to a temperature-compensated balance, a timepiece movement including the same, and a timepiece.

The balance of a watch has a balance spring that rotates about its axis, a balance wheel that is fixed to the balance through an arm, and a balance spring that serves as a power source for rotating the balance wheel in a normal and reverse direction. Yes. Since the balance of the balance with hairspring is a factor that determines the rate of the watch, it is designed to be within a predetermined range. However, the above-described vibration cycle may change due to various causes. For example, it may change due to changes in ambient temperature.
The vibration period T of the balance with hairspring can be expressed by the spring constant K of the balance spring constituting the balance with the inertia moment I of the balance with hairspring, and the relationship is expressed by the following formula 1.

  In the above formula 1, if the spring constant of the balance spring is increased, the vibration cycle of the balance spring is shortened, and if the spring constant of the balance spring is decreased, the oscillation cycle of the balance spring is increased. In other words, if the spring constant of the hairspring is increased, the phase of the balance spring is advanced, and if the spring constant of the hairspring is decreased, the phase of the balance spring is delayed. On the other hand, if the moment of inertia of the balance is increased, the vibration cycle of the balance is lengthened and the phase is delayed. When the moment of inertia of the balance with hairspring is reduced, the vibration cycle of the balance with hairspring is shortened and the phase advances.

  Generally, the material used for the balance wheel expands as the temperature rises. Therefore, the diameter of the balance wheel is increased, and the moment of inertia of the balance is increased. Further, since the Young's modulus of a material generally used for the hairspring has a negative temperature coefficient, the spring constant decreases as the temperature increases.

  From the above, the temperature characteristic of the balance of the balance with the balance tends to become longer as the ambient temperature rises. In order to correct this temperature characteristic, a method for adjusting the moment of inertia of the balance with hairspring is known.

  In the conventional balance with a balance, the arm and the balance wheel rotating around the balance stem are made of metals having different linear expansion coefficients. The balance wheel is nickel steel with a small linear expansion coefficient, and the arm is brass, and the linear expansion coefficient of the arm is larger than the thermal expansion coefficient of the balance wheel. Therefore, when the temperature rises, the shape of the balance wheel approaches an ellipse whose major axis is the position of the arm. The weight installed near the short axis of the ellipse is displaced inward in the radial direction in accordance with the temperature change, so that the moment of inertia of the balance with hairspring is reduced.

  The amount of change in the moment of inertia depends on the extension of the arm and the weight of the weight. In the case of the conventional metal arm, the amount of elongation is small. In order to secure a desired amount of change in moment of inertia, it is necessary to use a long arm and a large mass weight. However, using a long arm increases the diameter of the balance and presses a limited space within the watch movement. Also, because the large mass weight generally has a larger volume, the large mass weight screw requires more space to rotate with the balance and presses the limited space within the watch movement. In addition, when the weight of the balance with a long arm, a large-diameter tension ring, a heavy weight, or the like increases, the individual friction increases and wear of the parts is accelerated. Moreover, since the moment of inertia of the balance increases as the overall weight of the balance increases, more energy is required to drive the balance. In other words, a stronger power spring is required. A stronger spring is a thicker and wider spring, which increases the volume of the barrel for storing the mainspring and presses a limited space in the movement of the watch. In addition, a weight having a large mass impairs the weight balance of the balance with a high accuracy unless the position is accurately arranged, thereby reducing the accuracy of the timepiece. If there is an error in the displacement of the weight due to the deformation of the balance wheel, and there is a difference in the distance from the balance between the two weights that are rotationally symmetric around the balance, the center of gravity of the entire balance will deviate from the center. This shift will disturb the accuracy of the watch. In this case, the greater the mass of the weight, the more the accuracy of the timepiece is disturbed.

"Watch Adjustment" Hans Jendritzki, p10 Publisher Editions Antoine Simonin, 2006 reprint (first edition 1970)

  The present invention has been made in view of such circumstances, and the purpose thereof is a temperature-compensated balance, a movement for a watch, and a temperature-compensating balance that can secure an adjustment amount of the moment of inertia of the balance without greatly changing the weight and size of the balance. To provide a watch.

The present invention provides the following means in order to solve the above-described problems.
A temperature-compensated balance according to the present invention is a temperature-compensated balance having a balance stem that rotates about an axis, a balance wheel arranged around the balance, and a weight portion attached to the balance wheel. A first arm portion including a first base portion that is truly fixed, a first free end portion that is displaced in a radial direction centering on the balance stem with a temperature change, and a second base portion that is fixed to the balance wheel, A second arm portion having a second free end portion that is radially displaced with a temperature change; and a first abutting surface that abuts on the first arm portion and intersects the expansion and contraction direction of the arm. A second abutting surface that is in contact with the second arm portion, intersects with the expansion / contraction direction of the arm and is formed radially inward from the first abutting surface, and has a thermal expansion coefficient smaller than the thermal expansion coefficient of the arm. And an intermediate member.
According to such a configuration, it is possible to ensure a change amount of the moment of inertia according to the request.

  In the temperature compensation type balance according to the present invention, the first arm portion and the second arm portion expand and contract in the radial direction due to thermal expansion, and the intermediate member restricts the movement of the first free end portion and the second free end portion. Thus, the distance between the first base portion of the first arm portion and the second base portion of the second arm portion changes. That is, the distance between the balance and the balance wheel at both ends of the arm changes, and the balance of the balance wheel is deformed. Since the deformation amount of the thermal expansion of both the first arm portion and the second arm portion can be used, the deformation amount of the balance wheel is larger than that of the conventional configuration, and the weight attached to the balance wheel. The amount of displacement increases. Therefore, since the moment of inertia can be changed more greatly, an adjustment amount of the moment of inertia of the balance can be secured without largely changing the weight and size of the balance.

  The temperature-compensated balance according to the present invention further includes a hairspring serving as a power source for rotating the balance wheel, and the spring constant of the hairspring is made of a material that decreases as the temperature rises. It has a tendency to extend in the direction of expansion and contraction of the arm as the temperature rises, has a linear expansion coefficient larger than the linear expansion coefficient of the balance wheel, and the weight part is on a different circumference from the second base part of the second arm part in the balance wheel. Provided.

According to such a configuration, it is possible to ensure the amount of change of the moment of inertia according to the request without greatly changing the length of the arm and the weight of the weight, thereby suppressing fluctuations in the vibration cycle of the balance with the temperature change. be able to.
That is, since the spring constant of the hairspring is made of a material that decreases with increasing temperature, the vibration cycle of the balance with increasing temperature increases. On the other hand, as the temperature rises, the balance wheel deforms in a direction approaching an elliptical shape with the arm as the major axis. Since the weight is disposed at the position of the elliptical minor axis, the moment of inertia of the balance wheel is reduced, and the balance vibration cycle is reduced. Therefore, when these interact, the fluctuation | variation of the vibration cycle of the balance with the temperature change can be suppressed.

The intermediate member of the temperature compensation balance according to the present invention includes a first intermediate member having a first contact surface and a second intermediate member having a second contact surface, and the arm has a first intermediate member. Both ends of the member and the second intermediate member are brought into contact with each other, and a third arm portion having a linear expansion coefficient larger than that of the intermediate member is provided.
According to this configuration, it is possible to secure a larger amount of change in the moment of inertia according to the request. That is, in addition to the deformation amount of the thermal expansion of the first arm portion and the second arm portion, the deformation amount of the thermal expansion of the third arm portion can be used, so the length of the arm and the weight of the weight can be reduced. It is possible to ensure the amount of change of the moment of inertia according to the demand without greatly changing.

In addition, either one of the arm and the intermediate member of the temperature compensation balance according to the present invention has a restricting member that restricts relative movement between the arm and the intermediate member in a direction perpendicular to the expansion and contraction direction of the arm.
According to such a configuration, it is possible to prevent positional deviation between the arm and the intermediate member other than the direction in which the arm extends and contracts. Since the deformation of the arm can be used efficiently, the amount of change in the moment of inertia of the balance can be efficiently secured. Further, it is possible to prevent the balance of the balance of the balance from being lost due to the positional deviation between the arm and the intermediate member, thereby preventing the accuracy of the timepiece from being lost.

Moreover, the temperature compensation type balance regulating member according to the present invention regulates relative movement between the arm and the intermediate member in the circumferential direction centering on the balance.
According to this configuration, in addition to the above-described effects, it is possible to prevent the circumferential displacement between the arm and the intermediate member. Therefore, it is possible to prevent the position shift due to the reversing operation at the position where the balance swinging angle is most likely to occur, so that the deformation of the arm can be used efficiently. Therefore, the amount of change in the moment of inertia of the balance can be efficiently secured. Further, it is possible to prevent the balance of the balance of the balance from being lost due to the positional deviation between the arm and the intermediate member, thereby preventing the accuracy of the timepiece from being lost.

Further, the temperature compensation type balance regulating member according to the present invention regulates relative movement between the arm and the intermediate member in the axial direction of the balance.
According to such a configuration, the expansion / contraction direction of the arm can be restricted to a plane that is truly perpendicular. Therefore, in addition to the effects described above, the deformation of the arm can be efficiently used for the deformation of the balance wheel in the same plane.

The watch movement according to the present invention includes a barrel wheel having a power source, a train wheel that transmits the rotational force of the barrel wheel, and an escapement speed control mechanism that controls the rotation of the train wheel. The speed control mechanism has the above-described temperature compensation type balance.
According to such a configuration, it is possible to provide a timepiece movement that can secure a change amount of the moment of inertia according to a request.

A timepiece according to the present invention includes the timepiece movement according to the present invention.
According to such a configuration, it is possible to provide a timepiece that can ensure the amount of change in the moment of inertia according to the request.

  According to the temperature-compensated balance according to the present invention, it is possible to ensure an adjustment amount of the moment of inertia of the balance without greatly changing the weight and size of the balance.

It is a top view of the movement front side of the timepiece in Embodiment 1 of the present invention. It is a perspective view of the temperature compensation type balance in Example 1 of this invention. It is a top view of the temperature compensation type balance in Example 1 of this invention. It is the disassembled perspective view which expanded the arm part of the temperature compensation type | mold balance in Example 1 of this invention. It is a perspective view of the temperature compensation type balance in Example 2 of this invention. It is a top view of the temperature compensation type | mold balance in Example 2 of this invention. It is a perspective view of the temperature compensation type balance in Example 3 of this invention. It is a top view of the temperature compensation type | mold balance in Example 3 of this invention. It is a perspective view of the temperature compensation type balance in Example 4 of this invention. It is a perspective view of the temperature compensation type balance in Example 5 of this invention.

  Embodiment 1 of a timepiece for a timepiece according to the present invention will be described with reference to FIGS.

  First, a movement of a timepiece incorporating a balance will be described with reference to FIG. FIG. 1 is a plan view of the movement front side.

  As shown in FIG. 1, a movement 500 incorporated in a timepiece has a base plate 502 that constitutes a substrate of the movement 500. A winding stem 506 is rotatably incorporated in the winding stem guide hole 504 of the main plate 502. A dial (not shown) is attached to the rear side of the movement 500 in FIG. Generally, of the both sides of the main plate 502, the side on which the dial is arranged is referred to as the back side of the movement 500, and the opposite side of the side on which the dial is arranged is referred to as the front side of the movement 500. A train wheel composed of a plurality of gears incorporated on the front side of the movement 500 is referred to as a front train wheel, and a train wheel incorporated on the back side of the movement 500 is referred to as a back train wheel. By incorporating the movement 500 in a casing (not shown), a portable timepiece such as a wristwatch is assembled.

The axial position of the winding stem 506 is determined by a switching mechanism including a setting lever 508, a yoke 510, a yoke spring 512, and a back presser 514. The chisel wheel 516 is rotatably attached to a part of the winding stem 506. When the chimney wheel 516 is rotated in a state where the winding stem 506 is at the axially innermost position (0th stage), the chisel wheel 516 can be rotated via a pinwheel (not shown) attached to the winding stem. The round hole wheel 518 rotates in response to the rotation of the hand wheel 516. The square hole wheel 520 rotates in response to the rotation of the round hole wheel 518. The mainspring accommodated in the barrel complete 522 is wound up by the rotation of the square hole wheel 520. The escape wheel 530 rotates when the rotation of the barrel complete 522 is transmitted via the fourth wheel 528, the third wheel 526, and the second wheel 524. These fourth wheel 528, third wheel 526, second wheel 524, and barrel wheel 522 constitute a front wheel train. A minute hand and an hour hand are attached to the dial. The minute hand is attached to a cylindrical pinion (not shown) of the center wheel & pinion 526, and the hour hand is attached to an hour wheel (not shown) that receives the rotation of the hour pinion via a minute wheel (not shown). The tube kana is fixed to the center wheel & pinion 526 so as to be able to slip in order to adjust the time. The escapement and speed control device for controlling the rotation of the front wheel train includes a balance 532, an escape wheel 530, an ankle 534, and a hairspring 540 (not shown).
The receiving plate 560 holds the front wheel train and the escapement / speed control device with the main plate 502. The plurality of retaining screws 562 fix the receiving plate 560 to the main plate 502. The balance with hairspring 532 is disposed in close proximity to the front wheel train, escape wheel 530, ankle 534, retaining screw 562 and the like so as to effectively use the space inside the movement 500.

  Next, the temperature compensation balance according to the present embodiment will be described with reference to FIGS. 2 is a perspective view of the temperature compensated balance of the present embodiment, FIG. 3 is a plan view of the temperature compensated balance of the present embodiment, and FIG. 4 is an arm portion of the temperature compensated balance of the present embodiment. FIG.

  As shown in FIGS. 2 to 4, the temperature-compensated balance 1 of the present embodiment is a balance with the balance 2 serving as the center of rotation of the balance 1, the arms 4 extending in the radial direction about the balance 2, and the arms 4. A balance wheel 12 connected to the true wheel 2 and a weight 14 as a weight portion attached to the balance wheel 12 are provided. The arm 4 has a first arm portion 6 fixed to the balance stem 2 and a second arm portion 8 fixed to the balance wheel 12. An intermediate member 10 is disposed between the first arm portion 6 and the second arm portion 8. The weight 14 is disposed in a rotationally symmetrical manner with the balance 2 as the center on a circumference different from a portion where the second arm portion 8 of the balance wheel 12 is attached. The weight 14 provided with threading on the outer periphery is screwed to a portion of the balance wheel 12 having threading on the inner periphery.

The first arm portion 6 includes a substantially cylindrical first base portion 22 provided with a spring mounting hole 20, and a substantially rectangular parallelepiped first diameter portion 24 extending in the radial direction from the first base portion 22. The balance stem 2 can be rotated integrally with the first arm portion 6 by being press-fitted into the stem mounting hole 20. The first diameter portion 24 and the first base portion 22 are formed rotationally symmetric with respect to the stem mounting hole 20. The side opposite to the first base portion 22 in the first diameter portion 24 is referred to as a first free end portion 26, which is a free end whose distance from the first base portion 22 changes according to the surrounding temperature change. The first arm portion 6 has its first free end portion 26 displaced in the radial direction as the temperature changes, and its full length expands and contracts. The material of the first arm portion 6 is, for example, brass, and the linear expansion coefficient is 18 × 10 ⁻⁶ / K.

The second arm portion 8 includes a second base portion 32 in which the screw hole 30 is provided, and a substantially rectangular parallelepiped second diameter portion 34 that extends from the second base portion 32 toward the true side in the inner diameter direction. The second base portion 32 has a wall-like shape rising from the second diameter portion 34, and a screw hole 30 is cut perpendicular to the wall. The second diameter portion 34 is composed of a plurality of members, and each of the second diameter portions 34 is provided with rotational symmetry about the balance 2. The opposite side of the second diameter portion 34 to the second base portion 32 is referred to as a second free end portion 36, which is a free end whose distance from the second base portion 32 changes according to the surrounding temperature change. The second arm portion 8 has a second free end portion 36 that is displaced in the radial direction as the temperature changes, and the entire length of the second arm portion 8 expands and contracts. The material of the second arm portion 8 is, for example, brass, and the linear expansion coefficient is 18 × 10 ⁻⁶ / K.

The intermediate member 10 is disposed so as to be sandwiched between the first arm portion 6 and the second arm portion 8. The intermediate member 10 abuts on the first arm portion 6 and intersects with the expansion and contraction direction of the first arm portion 6. The intermediate member 10 abuts on the first arm surface 6 and the second arm portion 8 and expands and contracts the second arm portion 8. A second contact surface 10b that intersects the direction and is radially inward of the first contact surface 10a, and a substantially plate-like connection that connects the first contact surface 10a and the second contact surface 10b. The unit 10c is provided. The first contact surface 10a and the second contact surface 10b are formed in a step difference. The first contact surface 10a is formed substantially perpendicular to one surface of the vertically long plate-like connection portion 10c, and the second contact surface 10b is formed substantially perpendicular to the other surface of the connection portion 10c. That is, the first contact surface 10a, the connection portion 10c, and the second contact surface 10b are integrally formed in a substantially crank shape in plan view. Both surfaces of the substantially plate-like rectangular connecting portion 10 c face the side surfaces of the first arm portion 6 and the second arm portion 8, respectively. The material of the intermediate member 10 is, for example, Invar, and the linear expansion coefficient is 1.2 × 10 ⁻⁶ / K.

Next, a method for assembling the balance of the present embodiment will be described.
The outer peripheral wall surface of the second base portion 32 of the second arm portion 8 is brought into close contact with the inner periphery of the balance wheel 12 to which the weight 14 is attached. A fixing screw through hole 18 is formed in the balance wheel 12. The fixing screw 16 is screwed to the outer peripheral side wall surface of the second base portion 32 through the fixing screw through hole 18. In this state, the balance wheel 12 is arranged with a jig (not shown), and the balance stem 2 and the first arm portion 6 fixed to each other are arranged at the center of the balance wheel 12. Thereafter, the intermediate member 10 is inserted and disposed in a substantially crank-shaped gap generated between the first arm portion 6 and the second arm portion 8. The first contact surface 10a of the intermediate member 10 and the first free end portion 26 of the first arm portion 6, and the second contact surface 10b of the intermediate member 10 and the second free end portion 36 of the second arm portion 8 are: For example, it is fixed by bonding, welding, screws or the like. The relative positions of the first arm 6, the second arm 8, and the intermediate member 10 are fixed by a pressing member (regulating member) described later. The balance 1 is completed by attaching the hairspring 540 or the like.

Next, the function and effect of the configuration of this embodiment will be described.
Near the normal temperature, the balance wheel 12 has a circular shape. The length of the arm 4 is such that the balance wheel 12 maintains a circular shape. The length of the arm 4 is determined by the distance between the first base portion 22 of the first arm portion 6 and the second base portion 32 of the second arm portion 8.
The first arm portion 6 and the second arm portion 8 are disposed such that the side surfaces face each other. A connecting portion 10c of the intermediate member 10 is interposed between the opposing surfaces. Further, the first free end portion 26 is arranged in a step difference from the second free end portion 36, and is arranged radially outside the second free end portion 36 around the balance 2. As described above, since the first arm portion 6 and the second arm portion 8 are arranged so as to be interchanged, an increase in the overall length of the arm 4 near normal temperature is suppressed.

As the temperature rises, the first arm portion 6, the second arm portion 8, and the intermediate member 10 expand according to each linear expansion coefficient. The direction in which the first arm portion 6 extends from the first base portion 22 to the first free end portion 26 is opposite to the direction in which the second arm portion 8 extends from the second base portion 32 to the second free end portion 36. Has been placed. The first arm portion 6 expands in a direction in which the first base portion 22 and the first free end portion 26 are separated from each other. Similarly, the second arm portion 8 expands in a direction in which the second base portion 32 and the second free end portion 36 are separated from each other. The first free end portion 26 and the second free end portion 36 are in contact with the first contact surface 10a and the second contact surface 10b of the intermediate member 10, respectively. That is, the relative position between the first free end portion 26 and the second free end portion 36 is fixed via the intermediate member 10. Accordingly, as the first arm portion 6 and the second arm portion 8 expand, the distance between the first base portion 22 of the first arm portion 6 and the second base portion 32 of the second arm portion 8 increases. As the temperature rises, the connecting portion 10c of the intermediate member 10 also expands in the radial direction. However, since the linear expansion coefficient of the intermediate member 10 is smaller than the linear expansion coefficients of the first arm portion 6 and the second arm portion 8, the intermediate member 10 Can be prevented from canceling out the extension of the first arm portion 6 and the second arm portion 8.
Since the two members of the first arm portion 6 and the second arm portion 8 are provided as the members that thermally expand, it is possible to obtain about twice as much extension as the extension range due to the thermal expansion of one member. . Therefore, a large amount of change in the moment of inertia of the balance 1 can be secured. In addition, since the first arm portion 6 and the second arm portion 8 are arranged so as to be interchanged, the total length of the arm 4 near the normal temperature can be maintained as a single member.
Further, when the amount of change in the moment of inertia of the balance 1 is to be increased, it is necessary to increase the size of the weight 14. In this embodiment, a large amount of change in the moment of inertia of the balance 1 can be ensured without employing a large weight. Therefore, it is possible to incorporate a balance with a large moment of inertia without greatly changing the structure around the balance 1 of the movement 500. That is, the adjustment amount of the moment of inertia of the balance can be secured without largely changing the weight and size of the balance.
Even in the conventional example, if a material having a high linear expansion coefficient such as acrylic resin is used for the arm, it is possible to secure a large amount of extension of the arm, but the strength necessary for deforming the balance wheel into an elliptical shape is obtained. It is difficult. According to the present embodiment, a required amount of change can be ensured by using a high-strength material such as metal.

  Next, based on FIGS. 5 and 6, the balance with the balance of the second embodiment which is an embodiment different from the first embodiment will be described. FIG. 5 is a perspective view of the balance of the present embodiment, and FIG. 6 is a plan view of the balance of the present embodiment. In addition, the structure, operation | movement, and effect which overlap with description of Example 1 are abbreviate | omitted.

  In this embodiment, as shown in FIGS. 5 and 6, the intermediate member is divided into a first intermediate member 110 and a second intermediate member 111, and between the first intermediate member 110 and the second intermediate member 111. Is different from the above-described embodiment in that the third arm portion 107 is disposed.

  The intermediate member includes a first intermediate member 110 having a first contact surface 110a and a second intermediate member 111 having a second contact surface 111b. The first intermediate member 110 and the second intermediate member 111 have both ends. And a third arm portion 107 having a linear expansion coefficient larger than that of the intermediate member.

The first intermediate member 110 is disposed so as to be sandwiched between the first arm portion 106 and the third arm portion 107. The intermediate member abuts on the first arm portion 106 and intersects the expansion and contraction direction of the first arm portion 106 with the first abutment surface 110 a and the third arm portion 107 and expands and contracts the third arm portion 107. A third abutment surface 110d that intersects the direction and is radially inward of the first abutment surface 110a, and a substantially plate-like straight line that connects the first abutment surface 110a and the third abutment surface 110d. A square first connection part 110c is provided. The first contact surface 110a and the third contact surface 110d are formed in a step difference. The first contact surface 110a is formed substantially perpendicular to one surface of the vertically long plate-like first connection portion 110c, and the third contact surface 110d is substantially perpendicular to the other surface of the first connection portion 110c. It is formed. That is, the first contact surface 110a, the first connecting portion 110c, and the third contact surface 110d are integrally formed in a substantially crank shape in plan view. Both surfaces of the substantially plate-like first connection part 110c are opposed to the side surfaces of the first arm part 106 and the third arm part 107, respectively.

  The second intermediate member 111 is disposed so as to be sandwiched between the first arm portion 106 and the second arm portion 108. The second intermediate member 111 abuts on the second arm portion 108 and abuts on the second abutment surface 111 b and the third arm portion 107 intersecting with the expansion and contraction direction of the second arm portion 108. A fourth contact surface 111e that intersects with the expansion / contraction direction of the second contact surface 111b and is formed radially outward from the second contact surface 111b, and a substantially plate shape that connects the second contact surface 111b and the fourth contact surface 111e. 2nd connection part 111c is provided. The second contact surface 111b and the fourth contact surface 111e are formed in a step difference. The second contact surface 111b is formed substantially perpendicular to one surface of the vertically long plate-like second connection portion 111, and the fourth contact surface 111e is substantially perpendicular to the other surface of the second connection portion 111. It is formed. That is, the second contact surface 111b, the second connection portion 111c, and the fourth contact surface 111e are integrally formed in a substantially crank shape in plan view. Both surfaces of the substantially plate-like second connection part 111 are opposed to the side surfaces of the second arm part 108 and the first arm part 106, respectively.

Next, the function and effect of the configuration of this embodiment will be described.
In the vicinity of normal temperature, the first arm portion 106 and the third arm portion 107 are disposed so that the side surfaces face each other. A first connection part 110c of the first intermediate member 110 is interposed between the opposing surfaces. Further, the first arm portion 106 and the second arm portion 108 are disposed such that the side surfaces face each other. A second connecting portion 111c of the second intermediate member 111 is interposed between the opposing surfaces. As described above, the first arm portion 106 and the second arm portion 108 are arranged in a reversed manner, and the first arm portion 106 and the third arm portion 107 are arranged in a reversed manner, so that the temperature at a room temperature is around. Increasing the overall length of the arm is suppressed.

As the temperature rises, the first arm unit 106, the second arm unit 108, the third arm unit 107, the first intermediate member 110, and the second intermediate member 111 expand in accordance with each linear expansion coefficient. Due to the thermal expansion of the third arm portion 107, the distance between the first intermediate member 110 and the second intermediate member 111 increases. Then, since the distance between the first contact surface 110a and the second contact surface 111b also increases, the distance between the first base portion 122 of the first arm portion 106 and the second base portion 132 of the second arm portion 108 is increased. Can be larger.
Since the three members of the first arm portion 106, the second arm portion 108, and the third arm portion 107 are provided as members that thermally expand, approximately three times the expansion range due to the thermal expansion of one member. Can be obtained. Therefore, a large amount of change in the moment of inertia of the balance with hairspring 101 can be ensured. In addition, the first arm portion 106, the second arm portion 108, and the third arm portion 107 are arranged so as to be interchanged, so that the total length of the arm near normal temperature is maintained as a single member. can do.
Further, when the amount of change in the moment of inertia of the balance with hairspring 101 is to be increased, it is necessary to increase the size of the weight 114. In this embodiment, a large amount of change in the moment of inertia of the balance with hairspring 101 can be secured without employing a large weight. Therefore, it is possible to incorporate a balance with a large moment of inertia without greatly changing the structure around the balance of the movement.
If a material with a high coefficient of linear expansion such as acrylic resin is used for the arm in the conventional example, it is possible to secure a large amount of extension of the arm, but obtain the strength necessary to deform the balance wheel into an elliptical shape. It is difficult. According to the present embodiment, a required amount of change can be ensured by using a high-strength material such as metal.

  Next, based on FIG. 7 and FIG. 8, the balance with the balance of the third embodiment which is still another embodiment will be described. FIG. 7 is a perspective view of the balance of this embodiment, and FIG. 8 is a plan view of the balance of the balance. In addition, the structure, operation | movement, and effect which overlap with description of the above-mentioned Example are abbreviate | omitted.

  As shown in FIGS. 7 and 8, the present embodiment is different from the first embodiment in that the relative movement between the arm 204 and the intermediate member 210 is restricted. The arm 204 and the intermediate member 210 are restricted from relative movement in the direction perpendicular to the axial direction of the balance stem 202 and perpendicular to the expansion / contraction direction of the arm 204, that is, around the balance stem 202. Yes.

  Two second diameter portions 234 and 235 of the second arm portion 204 are disposed on both sides of the balance. These are respectively referred to as a second diameter portion A234 and a second diameter portion B235. The second diameter portion A234 and the second diameter portion B235 extend radially inward from the second base portion 232, and each end includes a second free end portion A236 and a second free end portion B237. ing.

  The intermediate member 210 includes two second contact surfaces and two connection portions. The two second contact surfaces A210b and the second contact surface B210f are in contact with the second free end A236 and the second free end B237, respectively. The two connection portions are referred to as a connection portion A 210 c and a connection portion B 210 g, respectively, and are located on both side surfaces of the first diameter portion 224. The first contact surface 210a, the connection portion A210c, and the connection portion B210g form a substantially U-shape. Both side surfaces of the first diameter portion 224 are regulated in the circumferential direction by being sandwiched between the connection portion A210c and the connection portion B210g. The side surface of the connecting portion A210c and the connecting portion B210g opposite to the first diameter portion 224 is sandwiched between the second diameter portion A234 and the second diameter portion B235 and the circumferential direction is restricted. That is, the connecting portion A 210 c or the connecting portion B 210 g plays a role of a restricting member that restricts the relative displacement between the first arm portion 206 and the second arm portion 208 in the circumferential direction around the balance 202. . The restricting members are arranged in rotational symmetry about the balance stem 202.

Next, the function and effect of the configuration of this embodiment will be described.
Since the connection portion A 210c or the connection portion B 210g regulates the relative displacement in the circumferential direction between the first arm portion 206 and the second arm portion 208, the first arm portion 206 or the second arm portion 208 accompanying a temperature change. Is prevented from deviating from the radial direction around the balance stem 202. Therefore, it is possible to prevent the weight balance of the balance of the balance from being impaired due to the circumferential displacement of the first arm portion, the second arm portion, and the intermediate member.
Further, the extension of the first arm portion 206 or the second arm portion 208 due to thermal expansion can be used for the extension of the arm 204 as it is. Therefore, the amount of change in the moment of inertia of the balance with hairspring 201 can be efficiently ensured without impairing the extension of the arm 204.
Further, the connecting portions 210c and 210g of the intermediate member 210 serve not only as the above-described intermediate member but also as a regulating member that regulates relative positional deviation between the arm and the intermediate member other than the arm expansion / contraction direction. Since it is a member, the space around the balance can be effectively used without adopting a complicated structure. This is effective in a space where the parts inside the watch are dense.

  Next, with reference to FIG. 9, a balance with a balance according to embodiment 4 which is still another embodiment will be described. FIG. 9 is a perspective view of the balance of the present embodiment. In addition, the structure, operation | movement, and effect which overlap with description of the above-mentioned Example are abbreviate | omitted.

  In this embodiment, as shown in FIG. 9, the relative movement in the axial direction of the balance stem 302 between the arm 304 and the intermediate member 310 is regulated by a pressing member 350 as a regulating member.

  In the intermediate member 310, a pressing member is fixed to the upper surface or the lower surface of the connection portions 310c and 310g. The upper surface and the lower surface are surfaces orthogonal to the true axial direction. The pressing member 350 may be integrally formed with the connection portions 310c and 310g, or may be fixed to both sides of the upper surface and the lower surface of the connection portions 310c and 310g. The pressing member 350 includes a fixing portion 351 that is fixed to the connection portions 310c and 310g, and a guide portion 352 that simultaneously guides the upper surface or the lower surface of the first arm portion 306 and the second arm portion 308. The substantially rectangular parallelepiped pressing member 350 has a beam shape with the fixing portion 351 as a fulcrum, and the beam portion is a guide portion 352. Since the guide portion 352 is slidably in contact with the upper and lower surfaces of the first arm portion 306 and the second arm portion 308, the relative relationship in the axial direction between the first arm portion 306 and the second arm portion 308 is achieved. Restricts misalignment. Therefore, the pressing member 350 plays the role of a pressing member that regulates the relative displacement between the first arm portion 306 and the second arm portion 308 in the true axis direction. The holding member 350 is arranged rotationally symmetrically about the balance stem 302. The intermediate member 310 has a plurality of connection portions, that is, a connection portion 310c and a connection portion 310g, and can also regulate displacement in the circumferential direction between the first arm portion 306 and the second arm portion 308.

Next, the function and effect of the configuration of this embodiment will be described.
As in the third embodiment, the connection portion A 310c or the connection portion B 310g regulates the relative displacement in the circumferential direction between the first arm portion 306 and the second arm portion 308, and thus the first arm portion 306 accompanying the temperature change. Alternatively, in addition to preventing the extension direction of the second arm portion 308 from deviating from the radial direction centering on the balance stem 302, the guide portion 352 is connected to the first arm portion 306 and the second arm portion 308. Since the relative positional deviation in the true axial direction is regulated, the situation in which the extension direction of the first arm portion 306 or the second arm portion 308 accompanying the temperature change is deviated from the axial direction of the balance stem 302 is also suppressed. Therefore, the balance of weight of the balance with respect to the balance of the balance with the first arm portion 306, the second arm portion 308, and the intermediate member 310 is prevented from being lost due to the positional deviation in the circumferential direction and the axial direction of the balance stem. be able to. Further, the extension of the first arm part 306 or the second arm part 308 due to thermal expansion can be used for the extension of the arm 304 as it is. Therefore, the amount of change in the moment of inertia of the balance with hairspring 301 can be efficiently ensured without impairing the extension of the arm 304.

  According to such a configuration, the expansion / contraction direction of the arm 304 can be restricted within a plane perpendicular to the balance stem 302. The deformation of the arm can be efficiently used for the deformation of the balance wheel in the same plane. Further, the balance of the balance of the balance with hairspring is also prevented from deviating from the center of rotation. Therefore, the moment of inertia of the balance can be adjusted efficiently.

  Next, with reference to FIG. 10, a balance with a balance according to the fifth embodiment, which is still another embodiment, will be described. FIG. 10 is a perspective view of the balance of the present embodiment. In addition, the structure, operation | movement, and effect which overlap with description of the above-mentioned Example are abbreviate | omitted.

  In the present embodiment, as shown in FIG. 10, the pressing member 450 restricts the relative movement of the arm 404 and the intermediate member 410 in the circumferential direction and the axial direction of the balance stem 402.

  The intermediate member 410 has a pressing member 450 fixed to the upper surface or the lower surface of the connecting portion 410. The upper surface and the lower surface are surfaces orthogonal to the true axial direction. The pressing member 450 may be integrally formed with the connection portion 410, and may be fixed to at least one of the upper surface and the lower surface of the connection portion 410. The pressing member 450 includes a fixing portion 451 fixed to the connection portion 410, a guide portion 452 that simultaneously guides the upper surface or the lower surface of the first arm portion 406 and the second arm portion 408, and a circumferential support surface 453. The guide portion 452 and the circumferential support surface 453 are slidably in contact with the upper surface, the lower surface, and the side surface of the first arm portion 406 and the second arm portion 408. Further, the circumferential support surface 453 and the axial support surface 452 surround the first arm portion 406, the second arm portion 408, and the intermediate member 410. That is, the pressing member 450 serves as a pressing member that restricts relative movement of the arm 404 and the intermediate member 410 other than in the radial direction. The pressing member 450 is disposed rotationally symmetrically about the balance stem 302.

  As mentioned above, although this invention has been demonstrated based on Examples 1-5, the specific structure of this invention is not limited to Examples 1-5. Design changes and the like within the scope not departing from the gist of the present invention are also included in the present invention.

  For example, in the second embodiment, the intermediate member is composed of two members, but may be composed of three or more members.

  For example, the guide surface 352 of the pressing member 350 according to the fourth embodiment may be configured to guide not only the upper and lower surfaces of the first arm portion 306 and the second arm portion 308 but also both side surfaces. With such a configuration, it is possible to simultaneously regulate the relative displacement between the first arm portion and the second arm portion in the true axis direction and the circumferential displacement around the balance.

  For example, the pressing member 450 in the fifth embodiment may be fixed to the first arm portion 406 or the second arm portion 408 instead of being fixed to the intermediate member 410. When fixed to the first arm portion 406, the axial support surface 452 of the pressing member 450 is slidably in contact with the intermediate member 410 and the upper and lower surfaces of the second arm portion 408. Even with this configuration, the same effect can be obtained.

1, 101, 201, 301, 401 Balance 2, 102, 202, 302, 402 Balance 4, 104, 204, 304, 404 Arm 6, 106, 206, 306, 406 First arm 8, 108, 208, 308, 408 Second arm part 10, 110, 210, 310, 410 Intermediate member 10a, 110a, 210a First contact part 10b, 111b, 210b, 210f Second contact part 10c, 110c, 111c Connection part 12, Ten Wheel 14, 114 Weight (weight part)
22, 122 1st base part 24, 224 1st diameter part 26 1st free end part 32, 132, 232 2nd base part 34 2nd diameter part 36 2nd free end part 107 3rd arm part 350, 450 Holding member (regulation) Element)

Claims (8)

In a temperature-compensated balance with a balance stem that rotates around the axis, a balance wheel arranged around the balance wheel, and a weight portion attached to the balance wheel,
A first arm portion that includes a first base portion that is fixed to the balance; a first free end portion that is displaced in a radial direction centered on the balance portion with a temperature change; and a first arm portion that is fixed to the balance wheel. An arm having two base portions and a second arm portion including a second free end portion that is radially displaced with a temperature change;
A first abutting surface that contacts the first arm portion and intersects with the expansion / contraction direction of the arm, and a first abutting surface that contacts the second arm portion and intersects with the expansion / contraction direction of the arm. A temperature-compensated balance with a second contact surface formed radially inward and having an intermediate member having a thermal expansion coefficient smaller than that of the arm. A balance spring serving as a power source for rotating the balance wheel;
The spring constant of the hairspring is composed of a material that decreases with increasing temperature,
The arm has a tendency to extend in the expansion and contraction direction of the arm as the temperature rises, and has a linear expansion coefficient larger than the linear expansion coefficient of the balance wheel,
The temperature-compensated balance according to claim 1, wherein the weight portion is provided on a different circumference from the second base portion of the second arm portion in the balance wheel. The intermediate member includes a first intermediate member having the first contact surface and a second intermediate member having the second contact surface,
Said arm includes a third abutment surface formed radially inward of the first contact surface of the first intermediate member, it is formed on the second radially outer than the contact surface of the second intermediate member fourth ends in the abutment surface is abutting, have a third arm portion coefficient of linear expansion than that of the intermediate member is larger that,
The temperature-compensated balance balance according to claim 2, wherein the third contact surface and the fourth contact surface intersect with an expansion / contraction direction of the third arm portion .   4. The temperature according to claim 2, wherein one of the arm and the intermediate member includes a restricting member that restricts relative movement between the arm and the intermediate member in a direction perpendicular to a direction in which the arm extends and contracts. Compensation balance.   The temperature compensating balance according to claim 4, wherein the restricting member restricts relative movement between the arm and the intermediate member in a circumferential direction centering on the balance.   The temperature compensating balance according to claim 4, wherein the restricting member restricts relative movement between the arm and the intermediate member in the axial direction of the balance.   2. A barrel wheel having a power source, a train wheel that transmits the rotational force of the barrel wheel, and an escapement speed control mechanism that controls rotation of the train wheel, wherein the escapement speed control mechanism is defined in claim 1. Watch movement with temperature-compensated balance.   A timepiece having the timepiece movement according to claim 7.

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