JP2021515897A - Slow and fast hand assembly for watches - Google Patents

Abstract

A toothed member (5) comprising at least one toothed portion (51) and a flexible structure (52) arranged below the root of the tooth of at least one toothed portion (51). ), Specifically a slow and fast needle, more specifically a fine adjustment slow and fast needle, or a part designed to mesh with a slow and fast needle or a fine adjustment slow and fast needle. [Selection diagram] Fig. 1

Description

The present invention relates to a toothed member. The present invention also relates to a system that includes the toothed member. The present invention further relates to a clockwork mechanism that includes the system and / or the toothed member. The present invention finally relates to a timepiece including the clockwork mechanism and / or the system and / or the toothed member.

Adjusting the amplitude of the balance mechanism to adjust the movement of the movement requires precision. This type of adjustment is occasionally provided by a gear system intended to reduce the movement of the adjustment slow and fast needles to achieve precision. However, the use of gears provides an operating gap between the teeth of the members that mesh with each other. This involves play between the teeth of the dentition and play compensation when the slow and fast needles are moved in the first direction and then in the second direction. These drawbacks are unacceptable in situations where the movement of the balance with hairspring is regulated.

An object of the present invention is to provide a toothed member capable of avoiding such a gap. Specifically, the present invention proposes a toothed member capable of guaranteeing precise driving of a toothed member without a dentition gap that interrupts this drive, specifically, a slow / fast needle.

The toothed member according to the present invention is defined in claim 1.

Various embodiments of the toothed member are defined in claims 2-8.

The system according to the present invention is defined in claim 9.

The clockwork mechanism according to the present invention is defined in claim 10.

The clock according to the present invention is defined in claim 11.

The accompanying drawings show an embodiment of a timepiece according to the present invention as an example.

FIG. 1 is a perspective view of an embodiment of a clock. FIG. 2 is a detailed perspective view of a toothed member according to an embodiment of a watch. FIG. 3 is a detailed perspective view of the slow / fast hand assembly of the embodiment of the timepiece. FIG. 4 is a detailed perspective view of the slow and fast hands of the embodiment of the timepiece.

An embodiment of the clock 200 will be described below with reference to FIGS. 1 to 4. The watch 200 is, for example, a small watch, especially a wristwatch. The watch includes a clockwork mechanism 100, especially a mechanical clockwork movement. The clockwork movement 100 is, for example, a manual winding type or an automatic winding type.

The clockwork movement 100 includes a balance wheel 1-swirl spring type 2 oscillator. In order to adjust the movement, the first slow / fast needle 10 for coarse adjustment having the slow / fast needle key 11 acting on the spiral spring 2 is around the swivel shaft 53 with respect to the cock 7 or the balance with hairspring connected to the plate 8. Moved to.

The whiskers support 4 holds the whiskers 3 to which the outer end of the spiral spring is attached.

The first slow / fast needle 10 is fastened on the second finely adjusted slow / fast needle 5 and accompanies the rotational movement of the latter around the shaft 53. However, the friction torque between the slow and fast hands 10 and the finely adjusted slow and fast hands makes it possible to make a rough change in the angular position between the two slow and fast hands using a watchmaking tool.

In order to enable the first slow and fast hands to be precisely rotationally driven around the shaft 53, the second slow and fast hands are mounted on the frame of the movement in a swivel connection, especially around the shaft 63 and on the cock 7 in a swivel connection. Includes a toothed sector 51 that meshes with the pinion 6.

Therefore, the rotation of the pinion 6 around the shaft 63 causes an angular displacement of the second slow and fast needle 5 around the swivel shaft 53. This makes it possible to change the length of the moving part of the spiral spring and adjust its movement.

To facilitate the rotation of the pinion 6, a special easily reachable drive engraving 9 is placed on the pinion 6. The engraving may be slot 9 intended to receive the tip of a screwdriver.

Thus, the clockwork mechanism 100 includes a system 300, particularly a slow and fast needle assembly type system including a beard holding 3, a beard holding support 4, a first slow and fast needle 10, a second slow and fast needle 5 and a pinion 6. ..

As shown in more detail in FIG. 2, in the illustrated embodiment, the toothed member is the second slow and fast needle 5. As mentioned above, the second slow and fast needle 5 includes a toothed sector 51 intended to mesh with the teeth 61 of the pinion 6.

The second slow and fast needle 5 also includes a flexible structure 52 located below the root of the tooth of the toothed sector 51.

The "flexible structure" is understood to be a structure that deforms when a load is applied and can return to its original shape when the load is removed. In other words, the flexible structure is a structure that is elastically deformable, particularly a structure that is elastically deformable in the radial direction with respect to the swivel shaft 53.

"Under the root of the tooth" means that when the flexible structure 52 is a toothed sector in the shape of a circular or circular arc, the diameter is smaller or slightly smaller than the tooth valley diameter of the toothed sector 51. It is understood to mean extending to. In other words, the flexible structure 52 is preferably located near the toothed sector 51. In this case, the separation between the tooth valley diameter and the flexible structure is, for example, about 0.2 mm. This separation is determined, for example, by the material or plurality of materials of the flexible structure and / or the thickness of the flexible structure measured parallel to the swivel shaft 53.

However, the flexible structure can be placed at any position between the toothed sector 51 and the swivel shaft 53.

Preferably, the flexible structure 52 of the second slow / fast needle 5 is watermarked. This means that the flexible structure 52 may have, for example, one or more circular windows or holes (not shown). As an alternative to circular holes, or in combination with circular holes, the flexible structure 52 may have openings or gaps of, for example, squares, rectangles, or other shapes.

Preferably, as shown in FIGS. 1 and 2, and as described above, the second slow and fast needle 5 is arranged so as to swivel around the swivel shaft 53. The flexible structure 52 extends, for example, around the swivel shaft 53 over the flexible angle sectors. The flexible angular sector preferably has the same or substantially the same amplitude as the angular sector in which the toothed sector 51 extends. Alternatively, the flexible angular sector may have a smaller or greater amplitude than the angular sector of the toothed sector 51.

According to a preferred embodiment, the flexible structure 52 has at least one elastic blade 522. Preferably, the flexible structure 52 is provided with a plurality of elastic blades 522. The blade 522 is oriented parallel or substantially parallel to the tooth root surface, i.e. parallel or substantially parallel to the cylindrical surface passing through the tooth root of the toothed sector 51, as shown in FIG. ..

At least two or more cutouts 521 are created on both sides of the blade 522 to form the blade. These cutouts 521 are preferably measured perpendicular to the root surface of the tooth and have the same or substantially the same thickness as the blade 522. More specifically, the cutout 521 is parallel to the blade 522. Alternatively, these cutouts 521 are thicker or thinner than the blade 522, and / or not parallel to the blade.

The "root surface of a tooth" is understood to be the surface containing or tangential to the base of the tooth.

For example, the blade 522 has a thickness of 0.06 mm measured perpendicular to the root surface of the tooth.

For example, the blade 522 has a length of 1 mm (measured parallel to the root surface of the tooth).

The toothed member 5 has a leg portion 523 at the end of the blade that connects the blade to the toothed sector 51. The leg 523 also connects the blade 522 to another blade 522. Finally, the blade 523 connects the blade 522 to the rigid body portion 54 of the second slow and fast needle 5. Preferably, the leg 523 extends radially or substantially radially with respect to the swivel axis 53, or perpendicularly or substantially perpendicular to the root surface of the tooth.

The length of the blade 522 is also measured between two contiguous legs 523 on a given side of the blade.

More preferably, the leg 523 connecting the first and second blades 522 to each other connects one end of the first blade 522 to the center or substantially the center of the second blade 522.

More preferably, all legs 523 connecting the first and second blades 522 to each other connect one end of the first blade 522 to the center or substantially the center of the second blade 522.

Alternatively, the legs 523 connecting the first and second blades 522 to each other have one end of the first blade at a different position on the second blade, eg, one-third or one-fourth the length of the second blade. You may connect to the position.

Preferably, the flexible structure 52 has multiple rows of blades 522, such as 2 or 3 or 4 or 5 or 6 rows of blades 522 arranged parallel or substantially parallel to the root surface of the tooth. In other words, these columns follow sectors of concentric or substantially concentric circles with centers located or substantially located on the swivel axis 53.

For example, the rigidity constant of the flexible structure 52 is Kr = 65 N / mm in the radial direction with respect to the shaft 53, and here Kt = 1000 N / mm in the tangential or normal radial direction with respect to the shaft 53. The radial direction is the direction passing through the axis 53-63, and the tangential direction is perpendicular to the line passing through the axis 53-63, where the force point is located at the point of contact between the dentition 51 and the dentition of the pinion 6. Direction.

Preferably, the radial stiffness constant Kr is smaller than the tangential stiffness constant Kt, and is particularly significantly smaller. For example, the ratio of the radial stiffness constant Kr to the tangential stiffness constant Kt is less than 0.1. Therefore, the deformation of the flexible structure is substantially radial, that is, directed in the direction passing through the shafts 53-63.

The distance between the swivel shaft 53 of the second slow and fast needle 5 and the rotary shaft 63 of the pinion 6 is predetermined. The predetermined shaft spacing is smaller than the shaft spacing commonly or customarily used for gears with the same dentition characteristics. In fact, the shaft spacing is customarily equal to the sum of the original radii of members 5 and 6, plus a gap of, for example, 4%. This ensures accurate gear movement with gaps in the dentition.

In the embodiments of FIGS. 1 to 4, the correction of the shaft spacing depends on the manufacturing tolerance of the parts and the rigidity of the elastic structure 52 of the second slow and fast needle 5. As a result, once the members 5 and 6 are engaged, the flexible structure 52 is elastically deformed into a compressed state. The compression is exerted between the swivel shaft 53 and the rotary shaft 63. The compression results in a permanent contact at multiple points between the teeth of the toothed sector 51 of the second slow and fast needle 5 and the teeth 61 of the pinion 6. There is always at least one contact between the two pairs of side surfaces of the teeth of members 5 and 6, which pushes the dentition into each other, with the dentition of the second slow and fast needle 5 and the dentition of the pinion 6. The gap between them is removed. The flexible structure 52 absorbs the deformation required for the members 5 and 6 to mesh with each other. Therefore, the meshing motion of the members 5 and 6 is never hindered and is very accurate. Therefore, the adjustment of the movement is also accurate and reliable. In fact, even a slight angular displacement of the pinion 6 is transmitted to the second slow and fast needle 5.

In the above-described embodiment, the flexible structure is provided only on the second slow / fast needle. However, as an alternative to the presence of a flexible structure on the second slow and fast needle, or in addition to the presence of a flexible structure on the second slow and fast needle, the flexible structure on the pinion, especially the flexible structure surrounding the hub of the pinion 6. It is also possible to provide a structure. In this case, the flexible structure connects the hub to the dentition 61 located around the flexible structure.

In the embodiments described above, the flexible structure was provided by forming a structure, especially a window, on the toothed member. However, the flexible structure is provided in an alternative or complementary manner by providing an element of elastically deformable material with appropriate rigidity between the dentition and the hub of the toothed member. May be good. The elastically deformable material may be a synthetic material, particularly an elastomer. The flexible structure is preferably made of steel or nickel alloy.

In the above-described embodiment, the slow / fast needle assembly includes a first rough adjustment slow / fast needle and a second fine adjustment slow / fast needle. However, the present invention is also applicable to slow and fast needle assemblies that include a single slow and fast needle (corresponding to the two slow and fast needles 5 and 10 of the above embodiment, but combined into one). ..

In the above embodiments, the present invention applies to slow and fast needle assembly systems. However, the present invention is intended for any toothed gear or rack, especially for any toothed gear or rack of a clockwork system where it is intended to form part of the gear for which dentition gaps must be restricted or removed. , Applicable.

Claims (11)

A toothed member (5) of the slow and fast needle type, especially the fine adjustment slow and fast needle type, or the slow and fast needle or the part type intended to mesh with the fine adjustment slow and fast needle.
With at least one toothed sector (51),
A flexible structure (52) disposed beneath the root of the tooth in the at least one toothed sector (51).
Toothed member (5). The flexible structure (52) is a watermarked structure.
The member (5) according to claim 1. The member (5) has a swivel shaft (53), and the flexible structure (52) spans angular sectors around the swivel shaft (53), particularly around the swivel shaft (53). The toothed sector (51) extends over an angular sector with an amplitude equal to or substantially equal to the amplitude of the extending angular sector.
The member (5) according to claim 1 or 2. The flexible structure (52) has an elastic blade (522), preferably a plurality of elastic blades (522), the blade (522) parallel to or substantially parallel to the root surface of the tooth. Aimed,
The member (5) according to any one of claims 1 to 3. The blade (522) has a leg (523) at its end that connects the blade to the toothed sector (51) or another blade (522) or a rigid body portion (54) of the member (5). In particular, it has legs (523) that extend radially or substantially radially with respect to the swivel axis (53).
The member (5) according to claim 4. The legs (523) connecting the first and second blades (522) to each other connect the ends of the first blade (522) to the center or substantially the center of the second blade (522), or the first. And the plurality of legs (523) connecting the second blades (522) to each other connect the ends of the first blades (522) to the center or substantially the center of the second blades (522).
The member (5) according to claim 5. The flexible structure (52) has a plurality of rows of blades (522), particularly in two or three or four or five or six rows, particularly parallel or substantially parallel to the root surface of the tooth. Has a blade (522),
The member (5) according to any one of claims 4 to 6. The flexible structure (52) is substantially radial in the radial direction with respect to the rotation axis (53) of the member.
The member (5) according to any one of claims 1 to 7. The member according to any one of claims 1 to 8, which meshes with the toothed gear (6) or the pinion, particularly with the toothed gear or the pinion of the member type according to any one of claims 1 to 8. The system (300), in particular the slow and fast needle assembly (3, 4, 5), comprising (5), the meshing results in compression of the flexible structure (52), in particular radial compression with respect to the swivel shaft (53). , 6). A clockwork mechanism (100), particularly a clockwork movement, comprising the system (300) according to claim 9 and / or the member (5) according to any one of claims 1-8. A watch (200) comprising the clockwork mechanism (100) according to claim 10 and / or the system (300) according to claim 9 and / or the member (5) according to any one of claims 1 to 8. , Especially watches.

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