CH700408B1 - Support assembly for a helical spring, equipped with the support structure equipped Unruh arrangement, and with the balance arrangement mechanical watch. - Google Patents

Abstract

The invention aims to provide a support structure for the coil spring which allows to minimize the adaptation of the deviation of a coil spring from a plane, and a disorder assembly which is equipped with this support arrangement, as well as a mechanical clock. A support structure for the coil spring 3 of a mechanical timepiece is provided with a pad height adjusting mechanism for displacing a pad 40 with respect to a pad support 30 in vertical directions D1, D2. The block 40 has a shaft portion 41 inserted into an insertion hole 33 of the pad support 30 and a disk-shaped flange portion 42; the pad height adjustment mechanism comprises a pad height adjusting body 50 equipped with a matching shaft portion 51 which mates with the pad carrier 30, and a fitting body main body portion 52 equipped with a dull cone 56 contacting surface which is eccentric with respect to the adapter shaft portion 51 at one end side thereof; and when the pad height adjustment body 50 is rotated about a central axis C of the adapter shaft portion 51, the reference surface in the shape of a dull cone 56 of the adapter body main body portion 52 presses against the one end edge 46 of the plate flange portion 42 of the pad 40 and causes moves the block 40 up or down with respect to the pad carrier 30 in the sense of D1, D2.

Description

Background of the invention

1. Field of the invention

The present invention relates to a support arrangement for a coil spring for a mechanical clock and in particular to a support arrangement for the coil spring, equipped with the support structure Unruhanordnung, and equipped with the Unruhanordnung mechanical clock.

The lying direction of the balance shaft is referred to in this specification as a vertical direction or as a height direction. In addition, conventionally, the side on which the upper balance bearing is disposed will be referred to as the upper side (upper), and the side on which the lower balance bearing is located will be referred to as the lower side (below).

2. Description of the Related Art

In a mechanical watch, the outer end portion of a coil spring is usually attached to a small block. The pad is press-fitted into a pad insertion hole of the pad support so as to be fixed therein, or it is inserted into the insertion hole and fixed therein by a set screw (see, for example, JP-UM-B-45-1071).

In both cases the adaptation of the position of the blocks in the hole of the pad carrier is not easy (in this description the direction of the hole in the pad carrier is considered to be "vertical direction" or "height direction" and the position [of the pad] is referred to as "height direction position [ of the block] »). When the height direction position of the peg is shifted, the coil spring whose inner end portion is supported by a spiral roll is not in a single plane but may be twisted (ie, the coil spring deviates from the plane), with the consequence that the performance the coil spring is affected in terms of the spiral power, the gear varies depending on the setting.

The patent JP-UM-B-45-1071 proposes an adjustment of the height position of the Klötzchens by a screw and a spring.

However, in a small mechanical watch, such as a wristwatch (watch), it is not yet easy to incorporate such a proposed spring structure in the pad area, which implies that this proposal is not realistic.

Summary of the invention

It is an object of the present invention to provide a spiral spring supporting structure of a mechanical timepiece which enables minimization of deviation of the spiral spring from the plane even in a small mechanical timepiece such as a wristwatch. and a disposition provided with the support assembly and a mechanical watch equipped with the structure.

Is provided, according to the present invention, a support structure, d. H. a support assembly for a coil spring of a mechanical timepiece equipped with a pad height adjusting mechanism for displacing a pad to which an outer end portion of the coil spring is attachable with respect to a pad support in one of two directions intersecting the plane in which the fixed coil spring extends, wherein the block includes a shaft portion and a plate-shaped flange portion, wherein the shaft portion is inserted into an insertion hole of the Klötzchenträgers, and wherein the plate-shaped flange portion is provided at one end of the shaft portion and protrudes from the insertion hole; wherein the pad height adjusting mechanism comprises a pad height adjusting body equipped with a fitting shaft portion which is parallel to the shaft portion of the pad and which is fittingly engaged with the pad carrier, and a fitting body main body portion provided with a reference surface in the form of a truncated cone, which is eccentric with respect to the adjustment shaft portion on one end side of the adapter shaft portion, and which is fixed to the adapter shaft portion; and wherein, when the pad height adjustment body is rotated about the central axis of the adapter shaft portion, the reference surface in the shape of the dull cone of the adapter body main body portion presses against an end edge of the plate flange portion of the pad such that the pad moves into one of the pad carrier with respect to the pad carrier Directions of his shaft area is movable.

In the supporting structure for the coil spring according to an embodiment of the present invention, the block has a shaft portion which is inserted into an insertion hole of the Klötzchenträgers, and a plate-shaped flange portion, which is provided at one end of the shaft portion, and which projects from the insertion hole ; and the pad height adjusting mechanism has a pad height adjusting body equipped with a matching shaft portion parallel with the shaft portion of the pad which matingly engages with the pad carrier, and a fitting body main body portion provided with a dull cone reference surface; which is eccentric with respect to the fitting shaft portion on one end side of the fitting shaft portion, and which is fixed to the fitting shaft portion, so that it is possible to achieve a structure in which, when the pad height adjustment body is rotated about a central axis of the fitting shaft portion, the reference surface in the form of a blunt cone of the fitting body main body portion presses against an end edge of the plate-shaped flange portion of the plug such that the pad moves in one of the directions with respect to the pad carrier In addition, the support structure for the coil spring according to the embodiment of the present invention is constructed such that, when the block height adjustment body is rotated about a central axis of the adjustment shaft portion, the reference surface is in the shape of a blunt cone of the adjustment body. Main body portion against an end edge of the plate-shaped flange portion of the pad such that the block is movable relative to the Klötzchenträger in one of the directions of its shaft portion », so that only by the rotation of the pad height adjustment body about the central axis of the adapter shaft portion, the reference surface in the mold of the truncated cone of the fitting body main body is pressed against an end edge of the plate-shaped flange portion of the stud such that the stud is movable with respect to the stud support in one of the directions of its shank portion which makes it possible to adjust the height of the pad with respect to the pad carrier so as to adjust the coil spring so that its spiral structure is arranged within a single plane. Therefore, in the support structure of the coil spring according to the embodiment of the present invention, it is possible to minimize the deviation of the coil spring from the plane.

Here, in the support structure for the coil spring according to the embodiment of the present invention, the block has a shank portion which is inserted into an insertion hole of the Klötzchenträgers, and a plate-shaped flange portion, which is provided at one end of the shank portion, and which projecting from the insertion hole; and the pad height adjusting mechanism has a pad height adjustment body which is provided with a matching shaft portion parallel with the shaft portion of the pad, which is fittingly engaged with the pad carrier, and a fitting body main body portion equipped with a dull-shaped reference surface Taper which is eccentric with respect to the fitting shaft portion on an end side of the fitting shaft portion and which is fixed to the fitting shaft portion, so that the plate-shaped flange portion of the plug, the adapter shaft portion of the pad height adjusting mechanism and the fitting body main body portion are formed of rigid bodies can be easily realized in a small mechanical clock, such as a wristwatch, this support arrangement for the coil spring. Thus, in the support structure for the coil spring according to the present invention, it is unique in providing a block height adjustment body equipped with a matching shaft portion parallel to the shaft portion of the block and fittingly engaged with the pad carrier, and a fitting body main body portion. is provided with a reference surface in the form of a blunt cone, which is eccentric with respect to the adapter shaft portion on one end side of the adapter shaft portion, and which is attached to the adapter shaft portion in the role of the pad height adjustment mechanism possible to adjust the height position of the pad. Moreover, the fitting body main body portion of this block height adjusting body is provided with a reference surface in the form of a blunt cone which is eccentric with respect to the fitting shaft portion, so that when the pad height adjustment body is rotated, the height of the stud is continuous adapt.

In the spiral spring supporting structure according to an embodiment of the present invention, the block height adjusting body in one of its end surfaces typically has a rotary slot.

In this case, it is possible only by the engagement of the front end of a screwdriver with the rotary slot and the rotation of the screwdriver to perform the adjustment of the height position.

In the coil spring supporting structure according to another embodiment of the present invention, the block height adjusting body further comprises a block height restoring area adapted to be engaged with the other end edge of the plate-shaped flange portion of the block, so that the block in FIG With respect to the Klötzchenträger in the other of the directions of its shaft portion is movable.

In this case, it is possible to restore the height position of the pad with respect to the pad carrier, thereby making it possible to perform the resizing of the height position. While it is typically desirable to define the height position of the lump through the fitting body main body portion, it is also possible, if desired, to use the lobe position defined in restoring the height position as it is as the fitting position. In this case, the default range functions as the height position matching body.

In the coil spring support structure according to another embodiment of the present invention, the block height recovery portion includes a recovery body having a restoration surface in the shape of a blunt cone on the other end side of the adjustment shaft portion, the restoration surface being eccentric with respect to the adjustment shaft portion is and is attached to the adjustment shaft area.

In this case, it is possible to move the block opposite in the height direction with respect to the pad carrier (in the recovery direction) by the rotation of the adjustment shaft with the aim of rotating the recovery body. In this case, the eccentricity direction of the recovery body is, of course, different from the eccentricity direction of the main body portion of the matching body; it is typically a direction which opposes the diameter direction. In addition, in this case, the interval (the distance) in the height direction between the restoration surface in the shape of a dull cone of the restoration body and the reference surface in the form of a dull cone of the fitting body main body portion is previously set to be at least not smaller than the thickness of the plate-shaped flange portion of the block. In this case, the recovery body can be formed of a rigid body so that it can be easily realized.

Moreover, in the support structure for the coil spring according to another embodiment of the present invention, the block height recovery portion comprises a recovery body shaft portion and a recovery body main body portion, wherein the recovery body shaft portion is parallel to the shaft portion of the pad and with the pad carrier in a and wherein the recovery body main body portion comprises a reference surface in the form of a blunt cone which is eccentric with respect to the recovery body shank portion at an end side of the recovery body shank portion and which is fixed to the recovery body shank portion. In this case, the recovery body main body portion may be formed of a rigid body, so that it can be realized very easily.

In this case, only by the rotation of the recovering body shaft portion for rotating the recovering body main body portion, it is possible to oppositely displace the blocks in the height direction (in the recovery direction) with respect to the pad carrier.

A balance structure, d. H. a disposition according to the present invention is equipped with a support arrangement for the coil spring according to the above description. In this case, it is possible to minimize the fluctuations or variations in the frequency of the disorder.

A mechanical watch according to the present invention is equipped with a disorder according to the above description. In this case, it is possible to minimize the influence of the mechanical clock setting on the gear.

Brief description of the drawings

[0021] <Tb> FIG. FIG. 1 is an explanatory perspective view of a trouble order according to a preferred embodiment of the present invention, which is provided with a coil spring supporting structure according to a preferred embodiment of the present invention. FIG. <Tb> FIG. 2A <SEP> is an explanatory frontal view, FIG. 2B is an explanatory side view as viewed in the direction of the arrow IIB of FIG. 2A, and FIG. 2C is an explanatory perspective view of the support structure for the coil spring of the disposition of FIG. <Tb> FIG. 3A is an explanatory frontal view, FIG. 3B is an explanatory side view, FIG. 3C is an explanatory view from below, and FIG. 3D is an explanatory perspective view of the height position adjusting mechanism of the pad associated with the plate-shaped flange portion of FIG Klötzchens is connected to adjust the height position of the support assembly for the coil spring of FIG. <Tb> FIG. 4A <SEP> is an explanatory frontal view, FIG. 4B is an explanatory side view as viewed in the direction of the arrow VIB of FIG. 4A, and FIG. 4C is a perspective view of the support structure for the coil spring according to a modification. <Tb> FIG. 5A <SEP> is an explanatory frontal view, FIG. 5B is an explanatory side view seen in the direction of the arrow VB of FIG. 5A, and FIG. 5C is a perspective view of the coil spring supporting structure according to another modification.

Description of the Preferred Embodiments

A preferred embodiment of the present invention will now be described with reference to the preferred embodiment shown in the accompanying drawings.

Fig. 1 shows a balance structure 2, d. H. a ratchet assembly mounted on the base support such as the motherboard (not shown) by a balance bridge 11 inside a housing 8 of a mechanical wristwatch 1, and FIG. H. a support assembly 3, for the coil spring 20, which is equipped with a Klötzchenträger 30, a block 40 and a height adjustment body in the form of a height adjustment pin 50 for the block 40.

The Unruhanordnung 2 has a balance 13, which is fixed to a balance shaft 12, and a coil spring 20, which is formed as a helical spring, wherein the inner end of the coil spring 20 attached to the balance shaft 12 spiral roller (not shown ), and wherein the outer end portion of the coil spring 20 is secured to the blocks 30 carried by the pad support 30. The area of the coil spring 20 in the vicinity of the outer end piece is engaged with a return pin 16 which is supported by the rear body 15.

The side at the upper end of the balance shaft is rotatably supported by an upper balance bearing 14 having the shape of the vibration inhibiting bearing, while the side at the lower end of the balance shaft is rotatably supported by a lower balance bearing (not shown) having the same structure like the upper balance bearing 14, and which is attached to the base support such as a motherboard (not shown).

The base end side of the rear body 15 is fitted with an outer frame of the upper balance bearing 14 so that it can perform a relative rotation, and a fork-shaped Rückerzeiger 15a at the base end side of the back body 15 is engaged with the eccentric fine adjustment lever 17; by the rotation of the fine adjustment lever 17, the rotational position of the rear body 15 and the engagement position of the return pin 16 are adjusted with respect to the coil spring 20, thus adjusting the actual length of the coil spring 20. Reference numeral 16a denotes a return pin lever for rotating the return pin 16, and reference numeral 16b denotes a back key which, by cooperation with the return pin 15, defines the outer engagement position of the coil spring.

The pad carrier 30 is provided with a long and narrow plate-like main body portion 31 and a C-ring engaging end portion 32 continuously formed at one end of the main body portion 31, the annular engaging end portion 32 matching with the outer frame of the upper interference bearing 14 is engaged that he can rotate about a central axis A. The main body portion of the pad support 30, that is, a so-called pad carrier main body portion 31 has on its other end side an insertion hole portion for the pad shaft 33 and an insertion hole portion for the height adjustment pin 34.

The block 40 has a shaft portion 41 which is inserted into the insertion hole portion for the pad shaft 33 of the pad carrier 30, and a plate-shaped flange portion 42 which is disposed on the nearer end side of the shaft portion 41 so as to be separated from the upper surface 35 the Klötzchenträgers 30 is separated. The shaft portion of the pad 40, that is, a pad shaft portion 41, has a fixing portion for the coil spring 44 to which the outer end portion of the coil spring 20 is fixed to the projecting end portion 43 which rotatably projects from the insertion hole portion for the pad shaft 33. The pad carrier 30 is also provided with a screw hole which is perpendicular to the insertion hole portion for the pad shaft 33, and which opens at the hole portion 33, with a stud screw 36 which is mounted in the screw hole. When the screw 36 is loose, the interval or gap G between the top surface 35 of the stud support 30 and the bottom surface 42a of the flange portion 42 of the stud 40 can be adjusted.

As shown in the enlarged view, particularly in Fig. 3, but also in Figs. 1 and 2, the height adjustment pin 50 has a first shaft portion 51 as the adjustment shaft portion, a first eccentric portion in the form of a blunt cone 52nd as the main body portion of the fitting body, a second shank portion 53, and a second eccentric portion in the shape of a blunt cone 54 as the recovery body. In the upper surface of the second eccentric portion in the form of a blunt cone 54, there is provided a rotary slot 55 which can engage with the front end of a screwdriver so as to extend along the diameter passing through a central axis Ca. The small-diameter portions of the first and second eccentric portions in the form of a blunt cone 52, 54 are both connected to the second shaft portion 53 continuously.

In this example, the fitting body of the height position of the pad is composed of the first shaft portion 51, the first eccentric portion in the shape of a blunt cone 52, and the second shaft portion 53. The height position adjusting mechanism of the pad is also composed of the first shaft portion 51, the first eccentric portion in the shape of a blunt cone 52, and the second shaft portion 53. The support structure for the coil spring 3 is composed of the height-position adjusting mechanism of the plug or the height-position adjusting body of the plug as described above, the pad 40, and the pad support 30 supporting it.

Both the first shaft portion 51 and the second shaft portion 53 are formed in a columnar structure whose center is the central axis Ca. The first shaft portion 51 is in fitting engagement with the insertion hole portion for the height adjustment pin 34 and can be rotated or rotated around the central axis C of the insertion hole portion for the height adjustment pin 34. In other words, since its central axis Ca coincides with the central axis C, the height adjusting pin 50 can be rotated or rotated around the central axis Ca which coincides with the central axis C. In some cases, the second shaft portion 53 may be omitted.

The first eccentric region in the form of a blunt cone 52 is formed as a blunt cone whose central axis C1 is shifted in the direction B1 relative to the central axis Ca by the amount ΔE, while the second eccentric region in the form of a blunt cone 54 is formed as a blunt cone whose central axis C2 is displaced with respect to the central axis Ca by the amount ΔE in the direction B2 opposite to the direction B1 (that is, in the direction -B1).

More specifically, irrespective of the rotational position (rotational position) of the height adjustment pin 50 about the central axis C or Ca, the magnitude of the eccentricity ΔE and the configuration of the blunt cone shape of the first and second regions are in the shape of a blunt cone 52, 54 is set so that when a surface in the form of a blunt cone 56 of the first region in the shape of a blunt cone 52 abuts or engages the lower end edge 46 of the flange portion 42 of the block 40, a surface in the shape of a blunt cone 57 of the second region in the form of a blunt cone 54 at the upper end edge 47 of the flange portion 42 of the block 40 is substantially adjacent to or separated from this.

In the case that the magnitude of the eccentricity ΔE is smaller than the radius R1 (which is typically the same size) of the first and the second area in the form of a blunt cone 52, 54, and the radius R2 of the plate-shaped flange portion 42, that is, when ΔE / R1 << 1 and ΔE / R2 << 1, and in the case where the inclination of the bluff cone envelope is about 30 to 60 degrees (typically about 45 degrees), when the height adjustment pin 50 rotates around the rotational position Central axis assumes Ca or C, provided that the surface in the form of a blunt cone 56 of the area in the form of a blunt cone 52 abuts the lower end edge 46 of the flange 42, and that the surface in the form of a blunt cone 57 of the area in the form of a blunt cone 54 abuts the upper end edge 47 of the flange portion 42, it is independent of the rotational or rotational position of the height adjustment pin 50 about the central axis Ca ode r C is able to maintain the state in which the surface in the form of a blunt cone 56 of the blunt cone 52 area abuts the lower end edge 46 of the flange portion 42, and in which the surface is in the shape of a blunt cone 57 of the area in the form of a blunt cone 54 at the upper end edge 47 of the flange 42 abuts. Accordingly, if certain deviations are taken into account, the distance between the surfaces in the form of a blunt cone 56, 57 in the lying direction of the central axes C, Ca should be made slightly larger than the thickness of the flange portion 42 of the block 40. However, this distance may For safety reasons also be made much larger.

In the following description, it will be assumed that the above-mentioned distance has been made large to some extent.

In the state in which the flange portion 42 of the block 40 is disposed between the first and second portions in the form of a blunt cone 52, 54 of the height adjustment pin 50, when the height adjustment pin 50 is rotated so that the center moves C1 of the first portion in the shape of a blunt cone 52 is brought closer to the flange portion 42 of the block 40, the lower edge portion 46 of the flange portion 42 of the block 40 opposite surface in the form of a blunt cone 56 gradually upward, that is in the direction D1 such that the block 40, the lower edge portion 46 of the flange portion 42 of which is engaged with the surface in the form of a blunt cone 56, moves continuously in direction D1. Therefore, the coil spring 20, whose outer end portion is attached to the lower end attachment portion 44 of the block 40, assumes the setting in which the position of its outer end portion has been displaced in the direction D1 and, if it is assumed that the outer end portion at one is in the direction D2 (ie, in the direction -D1) shifted position, the shift can be adjusted gradually and continuously by the rotation of the height adjustment pin 50. As a result, the coil spring 20 can take a helical shape in a single plane, so that the variation of the gear due to the adjustment can be minimized. Here, the rotation of the height adjustment pin 50 is realized by the engagement of the front end of a screwdriver or similar instrument with the rotary slot 55 and the corresponding rotation of the screwdriver. In this case, it is only possible by providing the height adjustment pin 50, which is a rigid body, to continuously adjust the height position of the block 40.

In the case that the position shown in Fig. 3 is adopted as a starting point, it is possible regardless of the direction of rotation of the height adjustment pin 50, the block 40 as a whole by means of the first portion in the form of a blunt To move cone 52 in direction D1 through the flange portion 42 of the block 40.

On the other hand, if the block 40 is to be returned to -D1, that is, in the direction D2, when the height adjustment pin 50 is rotated in the direction opposite to the direction when moving the block 40 in the direction D1, the surface in the form of a blunt cone 57 of the second region in the shape of a blunt cone 54 having the role of the restoring body engages the upper edge portion 47 of the flange portion 42 of the block 40, thereby allowing the block 40 is pressed down in the direction D2. In this case, the height adjusting pin 50 receives a force in the upward direction D1 so that a downward force in the direction D2 is applied to the pin 50 by the screwdriver to prevent the pin 50 from rising in the direction D1 , In order to prevent the displacement of the pin 50 in the direction D1 with respect to the pad carrier 30, the first shaft portion 51 of the pin 50 may be configured to protrude from the lower end of the pad carrier 30, the projecting end having a larger diameter.

When the block 40 has been brought into the desired height position (the position in the direction of D1, D2), the stud screw 36 is tightened, wherein the block 40 is fixed in position.

Half the circumference of the area in the shape of a blunt cone 52 is sufficient for operation, so that, for example, in Fig. 3A, the area 52F on the outer side of the dashed line can be omitted. In the supporting structure for the coil spring 3A in Fig. 4, the portions and the elements which are substantially the same as those in the support structure for the coil spring 3 of Fig. 2, but nevertheless different in certain respects, are given the same reference numerals the symbol A is attached thereto respectively, and the areas and the elements which are completely the same as those last mentioned are given the same reference numerals.

In the support structure for the coil spring 3A, the height adjustment pin 50A, instead of the first portion in the form of a blunt cone 52 as the main body portion of the fitting body, is provided with a first eccentric portion in the shape of a blunt cone 52A, the structure of which is along the cutting the sectional plane F is created; this coil spring supporting structure has the same construction as the coil spring supporting structure 3 of Fig. 2 except that the first portion in the form of a blunt cone 52A has a surface in the shape of a partial cone instead of the surface in the shape of a blunt cone 56 blunt taper 56A has been obtained in the shape of a partially blunted cone 56A by cutting along the cutting plane F.

The support structure for the coil spring 3A may function in the same manner as the support structure for the coil spring 3 of FIG. 2.

Instead of the structure in which the height adjustment pin 50, 50A is equipped with both a first portion in the shape of a blunt cone 52, 52A, which has the role of the main body portion of the fitting body, as well as with a second portion in the form of a It is also possible to adopt a structure in which the height adjustment pin 50B is provided only with a first portion in the form of a blunt cone 52B having the role of the fitting body, and in which another pin 60 is provided with a second portion in the form of a blunt cone 54B having the role of the recovery body.

In this example, the fitting body of the height position of the stud is composed of the first shaft portion 51, the first eccentric portion in the shape of a blunt cone 52A, and the second shaft portion 53. The height position adjusting mechanism of the pad is also composed of the first shaft portion 51, the first eccentric portion in the shape of a blunt cone 52A, and the second shaft portion 53. The supporting structure for the coil spring 3A is composed of the matching body of the height position of the peg or the adjusting mechanism of the height position of the peg as described above, the peg 40, and the peg carrier carrying it.

In the supporting structure for the coil spring 3B of Fig. 5, the areas and the elements which are substantially the same as those in the support structure for the coil spring 3, 3A of Figs. 2 and 4, but nevertheless in some points otherwise, given the same reference numerals with the symbol B attached thereto respectively, and the areas and elements which are the same as the last mentioned are given the same reference numerals.

In the support structure for the coil spring 3B, the height adjustment pin 50B has the same structure as the first portion in the shape of a blunt cone 52 except that the second portion in the shape of a blunt cone is missing, that the rotation slot 50B on a upper surface of the second shaft portion 53B is provided, and that the second shaft portion 53B has a large diameter.

The recovery pin 60, which is provided with a second portion in the form of a blunt cone 54B as the recovery body, has substantially the same structure as the height adjustment pin 50 except that instead of the first portion in the shape of a blunt cone 52 Column area is provided with a large diameter. In other words, the recovery pin 60 is provided with a first shaft portion or the first pillar portion 61, similar to the first shaft portion or the first pillar portion 51, a second shaft portion or the second pillar portion 63, similar to the second shaft portion or the second pillar portion 53, and a second pillar portion 63 Like the first pillar portion 51 of the height adjustment pin 50B, the first pillar portion 61 of the recovery pin 60 rotatably mates with a hole portion 34B which is similar to the one of the dull head 54B the hole portion 34 disposed in the main body portion 31 of the pad support 30.

In the supporting structure for the coil spring 3B, when the surface in the shape of the blunt cone 57B of the second region in the shape of the blunt cone 54B of the recovery pin 60 is disposed at a rotational position which is different from the upper edge region 47 of the flange portion 42 of FIG Block 40 is sufficiently removed, the height adjustment pin 50B is rotated, the surface in the shape of the blunt cone 56 of the first region in the shape of the blunt cone 52 of the height adjustment pin 50B, the lower end edge 46 of the flange portion 42 of the block 40 in the direction D1 upwards presses and makes it possible to adjust the height position of the block 40.

On the other hand, when the block 40 has moved to a sufficiently high position, the recovery pin 60 is rotated to a state in which the first portion in the shape of the blunt cone 52 of the height adjustment pin 50B is located at a rotational position which is sufficiently separated from the lower edge portion 46 of the flange portion 42 of the block 40, wherein the surface in the shape of the blunt cone 57 of the second region in the shape of the blunt cone 54B of the recovery pin 60, the lower end edge 47 of the flange portion 42 of the block 40 in pushes the direction D2, making it possible to restore the block 40 in the lower position.

In this example, the fitting body of the height position of the pad is composed of the first shaft portion 51, the first eccentric portion in the shape of a blunt cone 52, and the second shaft portion 53B. The height position adjusting mechanism of the pad is also composed of the first shaft portion 51, the first eccentric portion in the shape of a blunt cone 52, and the second shaft portion 53B. The supporting structure for the coil spring 3A is composed of the matching body of the height position of the peg or the adjusting mechanism of the height position of the peg as described above, the peg 40, and the peg carrier carrying it. The recovery body includes the recovery pin 60.

Claims (7)

A supporting structure (3) for a coil spring (20) of a mechanical timepiece (1) provided with a pad height adjusting mechanism for displacing a pad (40) to which an outer end portion of the coil spring (20) is fixable with respect to Pad carrier (30) in one of the two directions (D1, D2) intersecting the plane in which the attached coil spring (20) extends, wherein the pad (40) comprises a shaft portion (41) and a disk-shaped flange portion (42), wherein the shaft portion (41) is inserted into an insertion hole of the Klötzchenträgers (30), and wherein the disk-shaped flange portion (42) one end of the shaft portion (41) is provided and projects from the insertion hole; wherein the pad height adjustment mechanism comprises a pad height adjustment body (50) which is equipped a fitting shank portion (51) which is parallel to the shank portion (41) of the block (40) and which mates with the shoe support (30), and a fitting body main body portion (52) provided with a reference surface in the form of a blunt cone (56) which is eccentric with respect to the fitting shaft portion (51) on an end side of the fitting shaft portion (51) and which at the fitting shaft portion (51); 51) is attached; and wherein, when the pad height adjustment body (50) is rotated about the central axis (C) of the adapter shaft portion (51), the reference surface in the shape of the blunt cone (56) of the adapter body main body portion (52) abuts against an end edge (46) of the disk - shaped flange portion (42) of the block (40) such that the block (40) with respect to the Klötzchenträger (30) in one of the directions (D1) of its shaft portion (41) is movable. A support structure (3) for a coil spring (20) according to claim 1, wherein said block height adjustment body (50) has a rotation slot (55) in one of its end surfaces. A coil spring support assembly (20) according to claim 1 or 2, wherein the block height adjustment body (50) further comprises a block height recovery portion adapted to engage with the other end edge (47) of the disk flange portion (42) of the stud (40), so that the stud (40) is movable relative to the stud carrier (30) in the other of the directions (D2) of its shank portion (41). A coil spring support structure (3) according to claim 3, wherein said block height recovery portion comprises a recovery body (54) having a recovery surface in the form of a blunt cone (57) on the other end side of said adjustment shaft portion (51) wherein the restoration surface is eccentric with respect to the adapter shaft portion (51) and is secured to the adapter shaft portion (51). A coil spring support assembly (3) according to claim 3, wherein the block height recovery portion comprises a recovery body shank portion (53) and a recovery body main body portion, the recovery body shank portion (53) being connected to the shank portion (41) of the block (40) is parallel with and is in mating engagement with the pad carrier (30), and wherein the recovery body main body portion includes a reference surface in the form of a blunt cone (57) which rests against the recovery body shank portion (53) End side of the recovery body shaft portion (53) is eccentric and which is fixed to the recovery body shaft portion (53). Disruption arrangement equipped with a support structure for a coil spring (20) as claimed in any one of claims 1 to 5. 7. Mechanical watch, equipped with a Unruhanordnung as claimed in claim 6.