CH718324A2 - Watch case with rotating bezel and bezel locking mechanism. - Google Patents

Abstract

The present application relates to a watch case (1) with a rotatably mounted bezel (3) and a mechanism for locking the bezel (3), which comprises a pusher (7) that is linearly movable along a longitudinal axis (2) and rotatably mounted about the longitudinal axis. The pusher (7) has a groove for receiving an actuating body (18), which is arranged on a lateral surface of the pusher (7) and which has a first region with a first depth of the groove. The first area includes a tangential portion of the groove. The groove comprises a second area which has a first axial section (11), the groove in the first axial section (11) at least partially having a second depth which is greater than the first depth. The actuating body (18) is in a first position of the pusher (7) in the first area of the groove and interacts with a structure (19) of the bezel (3) to secure the bezel (3) against rotation. The actuating body (18) is in a second position of the pusher (7) in the first axial section (11) of the groove with the second depth, so that due to the greater depth of the groove the actuating body (18) is not connected to the structure (19) the bezel (3) interacts and the bezel (3) is freely rotatable.

Description

technical field

The invention relates to a watch case with a rotating bezel and a mechanism for locking the bezel.

State of the art

In the prior art, some mechanisms are known to lock a rotating bezel in a specific position. A construction in which a locking groove with engaging teeth is arranged on a rear surface of the bezel is often used. In the casing ring of the watch there is a steel ball which can be brought into contact with the meshing teeth, whereby a coil spring presses the steel ball against the meshing teeth.

[0003] CH 700 807 B1 (Seiko) describes another mechanism in which a bezel is rotatably inserted into an insertion groove of a casing ring of a timepiece. A detent is vertically movably disposed in a stepped bore of the caseband and is pressed against an engaging portion of the bezel. An actuator body with a recess forming a sloping lifting surface is seated in an insertion bore of the casing ring and crosses the lower end of the stepped bore at right angles. The actuator is urged to a position where a closure surface thereof closes the lower end of the stepped bore. The actuating member limits the movement of the locking member through the locking member when the locking member is resting on the locking surface, but releases the locking member and allows its vertical movement when the locking member is allowed to fall into the recess.

The CH 715 158 A2 (Tissot) discloses another mechanism in which a rotatable crown is arranged in a radial bore. The crown can be screwed into the bore and has a conical section which interacts with an engaging element. When screwing in the crown, the engaging element is pressed against an underside of the bezel to lock it. When the crown is loosened, the engagement element is released, allowing the bezel to rotate freely.

The CH 673 197 A3 (Manufacture de boîtes de montres MRP SA) describes a mechanism for locking a rotatable bezel with a circumferential toothing, in which a spring-loaded engagement element engages. The mechanism also has means with which the engagement element can be locked in one of the teeth.

[0006] Secure locking of the bezel is particularly important for diving watches, since the diving time is monitored with the bezel.

Presentation of the invention

The object of the invention is to create a watch case belonging to the technical field mentioned at the outset, which has a mechanism for securely locking a rotatable bezel.

The solution to the problem is defined by the features of claim 1. According to the invention, the watch case with a rotatably mounted bezel has a mechanism for locking the bezel, which has a pusher that is linearly movable along a longitudinal axis and rotatably mounted about the longitudinal axis. The pusher has a groove for receiving an actuating body, which is arranged on a lateral surface of the pusher and which has a first region with a first depth of the groove. The first area includes a tangential portion of the groove. The groove comprises a second region which has a first axial section, the groove in the first axial section at least partially having a second depth which is greater than the first depth. The actuating body is in a first position of the pusher in the first region of the groove and cooperates with a structure of the bezel to secure the bezel against rotation. The actuating body is in a second position of the pusher in the first axial section of the groove with the second depth, so that due to the greater depth of the groove the actuating body does not interact with the structure of the bezel and the bezel is freely rotatable.

The locking of the bezel can be canceled by rotating the pusher about the longitudinal axis and the subsequent movement of the same along its longitudinal axis. Accordingly, the bezel can be securely locked again by the reverse sequence of movements.

The watch case is preferably a watch case as known in the art. In particular, the watch case has a case ring, which preferably has the shape of a cylinder ring. The casing ring is preferably made of a metal or an alloy. A cover glass is preferably attached to a front side of the casing ring, while a removable base plate is preferably screwed onto the rear side of the casing ring.

The housing also has a clockwork which is held in particular by a frame or retaining ring in the housing ring. A dial with clock hands, which are driven by the clockwork, is preferably arranged between the clockwork and the cover glass. The clockwork can be a mechanical clockwork or an electronic clockwork, e.g. B. a quartz movement.

[0012]More preferably, two strap attachments are attached to the housing, to which a watch strap can be attached. The watch case preferably has a crown, for example to wind the clockwork and/or set the time. The watch case can also have at least one additional pusher to operate other functions of the movement, such as a chronometer function.

The watch case is preferably secured against the ingress of water from the outside by the arrangement of seals, in particular in the form of sealing rings. The watch case is preferably a watch case for a diving watch.

The bezel is preferably arranged in a bezel insert groove in which it is rotatably mounted relative to the watch case.

The pusher is preferably arranged in a bore of the watch case, in particular a radial bore in the casing ring. The bore is preferably designed as a blind hole. The pusher is preferably mounted in the bore so that it can rotate along its longitudinal axis and can be displaced along the longitudinal axis. The longitudinal axis of the bore coincides with the longitudinal axis of the pusher. The pusher is preferably cylindrical in shape, with a first end of the pusher protruding from the bore preferably being rounded or having an enlarged gripping surface, for example in the form of a disc with a larger diameter. In order to increase the grip of the push button, the lateral surface of the push button can have at least some knurling, ribbing or grooves. The watch case preferably has means with which the pusher can be secured against falling out of the casing ring or the bore. These means preferably additionally limit the travel that the pusher can be moved linearly along its longitudinal axis within the bore of the caseband, so that the pusher can only be moved a certain distance within the bore.

The groove preferably has a round, oval, rectangular or polygonal cross section. The depth of the groove extends from the lateral surface of the pusher to a point within the groove that is at the greatest distance from the lateral surface.

The tangential section of the groove preferably extends only over part of the circumference of the lateral surface of the pusher, ie over less than 360° of the circumference, preferably less than 270°. The tangential portion preferably extends at right angles relative to the longitudinal axis of the pusher. The tangential portion is preferably located in a region of the pusher which is more than 10% but less than 50% of the length of the pusher along the longitudinal axis from one end of the pusher, in particular from the second end of the pusher which is located within the caseband or the bore is arranged.

In addition to the tangential section, the first region of the groove can also have other sections which, in particular, have a different orientation than the tangential section on the lateral surface.

The second region of the groove preferably only has the first axial section. In certain embodiments, however, the second area can also have additional sections which, in particular, have a different alignment on the lateral surface than the first axial section. The first axial section is aligned parallel to the longitudinal axis of the pusher. The first axial section of the groove preferably extends to one end of the pusher, in particular to the second end of the pusher, which is arranged within the housing ring or the bore.

In the first axial section, the depth of the groove increases from the first depth to the second depth. The increase in depth may be continuous or discontinuous, e.g. B. stepwise or in the form of a curve. The curve can be in the form of an arc of a circle, a hyperbola, a parabola or any other suitable shape. The curve can be concave or convex relative to the lateral surface of the pusher.

The first position of the pusher is a position in which a rotational movement of the bezel is prevented by an interaction of the operating body with the structure of the bezel, that is, the bezel is locked. This is the case when the groove has the first depth. The second position is a position in which the bezel is freely rotatable since there is no interaction between the operating body and the structure of the bezel. Since the groove is relatively long, a person skilled in the art will understand that the pusher according to the movement according to the invention not only has a first and a second position, but all positions that the actuating body occupies along the groove and in which the actuating body with the Structure of the bezel cooperates to secure the bezel against rotational movement, to be understood as the first position within the meaning of the present application. Accordingly, all positions that the actuating body assumes along the groove and in which a free rotation of the bezel is possible are also to be understood as the second position within the meaning of the present application.

The actuator body is of a suitable shape to be received and moved in the groove. The actuating body preferably has a cross section and a size that allows the actuating body to move with as little play as possible within the groove. The actuating body is preferably arranged and mounted on the watch case or the case ring in such a way that it cannot be moved relative to the case ring, except along a radial axis which projects radially from the lateral surface of the pusher.

The rotation and linear movement of the pusher moves the actuating body within the groove so that it can be moved along the tangential section and the first axial section and any other sections.

When the actuating body is or is being moved within the first region with the first depth of the groove, the actuating body interacts with a structure of the bezel in order to secure it against rotational movement, i.e. to lock the bezel. In this case, the actuating body interacts either directly with the structure of the bezel or also indirectly via at least one further element which is arranged between the actuating body and the structure of the bezel.

When the actuating body is moved in one direction within the first axial section, the actuating body can be linearly displaced away from the bezel along the radial axis due to the changing depth of the groove. As a result of this displacement, the operating body no longer interacts with the structure of the bezel, so that it can be rotated freely. A corresponding movement of the actuating body along the first axial section in the opposite direction moves it towards the first region of the groove with the first depth, with which the actuating body is correspondingly displaced along the radial axis towards the bezel. As a result, the actuating body again interacts with the structure of the bezel, which secures it against rotation, i. H. is locked.

The structure of the bezel is arranged in particular on an underside of the bezel, which is directed towards the watch case or the casing ring. The structure preferably has a multiplicity of teeth or indentations in which the actuating body or another element which is arranged between the actuating body and the structure engages when the actuating body is in a first position.

By rotating the pusher, the actuating body can be displaced along the tangential section.

The actuating body is preferably a sphere. A ball can be moved particularly easily and only with little resistance within the groove.

Alternatively, the actuating body can also be configured differently, for example as a pin. It is only important that the actuating body can be moved within the groove.

The tangential section preferably extends over 160° to 200°, in particular over 180°, of the circumference of the lateral surface of the handle.

[0031] The groove preferably has a second axial section in the first region. This enables the pusher to be locked in the first position, in particular against the rotational movement about the longitudinal axis, so that an unintentional rotation of the pusher can be prevented when the actuating body is located in the second axial section.

The second axial section is preferably less long than the first axial section. More preferably, the first axial section as well as the second axial section point in the same direction away from the tangential section. The second axial section is preferably parallel to the first axial section.

The tangential portion of the groove is preferably between the first axial portion and the second axial portion.

Preferably, the first axial section and optionally the second axial section are directed away from the tangential section in the direction of the center of the watch case. This means that the first axial section as well as—if present—the second axial section point in the direction of the second end of the pusher, which is arranged inside the housing or the housing ring.

Preferably, the watch case has a spring biasing the pusher in a first direction away from the center of the watch case.

In particular, if the first axial section points in the direction of the center of the watch case, after the pusher has been turned and the first axial section has been reached by the actuating body, the pusher is pressed outwards from the watch case, with the actuating body in the first axial section is moved in the direction of the second depth and held there. As a result, the pusher can hardly be unintentionally moved linearly during rotation of the bezel, for example to set a diving time or the like, so that the actuating body is moved back to a position within the groove at which the groove has the first depth, with which the rotation of the bezel would be blocked.

If the groove has a second axial section, which also points in the direction of the center of the movement, the spring can be used to ensure that the pusher is pressed outwards relative to the watch case as soon as the actuating body reaches the second axial section and the actuating body is moved into said second axial section. Since the pusher is biased by the spring relative to the watch case outwards, i.e. in a direction directed away from the center of the watch case, the actuating body is prevented from being unintentionally moved in the second axial section and reaching the tangential section. This prevents the handle from turning unintentionally. This enables the handle to be reliably locked in the first position.

Preferably, the depth of the groove in the first axial section increases steadily from the first depth to the second depth. As a result, the force required to move the actuating body back along the first axial section within the groove to the first depth is uniform.

The pusher is preferably located at the 10 o'clock position of the watch case. The push-button is thus located at a point in the movement at which the probability of an unintentional contact by a wearer of a watch with the watch case is as small as possible.

The bezel can preferably be rotated in only one direction of rotation, in particular counterclockwise. For this purpose, the bezel and/or the housing ring has appropriate means which only allow rotation in one direction.

In particular with diving watches, it is advantageous if the bezel can only be rotated counterclockwise.

The present application also relates to a watch with a watch case according to the above description.

Furthermore, the present application relates to a pusher for a watch case according to the above description. The handle preferably has a cylindrical base body with a lateral surface. A groove is arranged on the lateral surface, which groove has a first region with a first depth of the groove, the first region comprising a tangential section and a second region which has a first axial section. In the first axial section, the groove has at least partially a second depth which is greater than the first depth

The tangential section preferably extends over 160° to 200°, in particular over 180°, of the circumference of the lateral surface of the pusher.

The groove preferably has a second axial section in the first region, the tangential section of the groove being located between the first axial section and the second axial section.

[0046] Further advantageous embodiments and combinations of features of the invention result from the following detailed description and the entirety of the patent claims.

Brief description of the drawings

The drawings used to explain the exemplary embodiment show: FIG. 1 an exemplary embodiment of a watch case according to the invention in a plan view; Fig. 2 - 5 isometric views of an exemplary embodiment of the pusher from different perspectives; FIGS. 6-8 detailed shots of the watch case according to FIG. 1 in the area of the pusher as a sectional view with the pusher in different positions; 9 shows an exemplary embodiment of a bezel from below in an isometric view.

In principle, the same parts are provided with the same reference symbols in the figures.

Ways to carry out the invention

1 shows an exemplary embodiment of a watch case 1 according to the invention in a plan view. The watch case 1 comprises a case ring 2 which is made in particular of a metal or an alloy. A bezel 3 is rotatably arranged on the housing ring 2 . Minute subdivisions are printed or engraved on the bezel 3 in a known manner, shown as an example using the upper right quadrant. The watch case 1 also has a cover glass 4, in particular made of sapphire glass, and a crown 5 for setting the time and, if necessary, for winding the movement or for setting other functions, such as a date display. Below the cover glass 4, in a known manner, there is a dial with clock hands and underneath a clock mechanism (none of which are shown). The watch case also has two lugs 6.1, 6.2, with which the movement 1 can be connected to a bracelet (not shown). In the embodiment of the watch case 1 shown, a pusher 7 is arranged at the 10 o'clock position, which is part of a mechanism for locking the bezel 3 . The pusher 7 can be rotated about its longitudinal axis L and moved linearly along this longitudinal axis L in order to secure the bezel 3 against a rotary movement or to enable the bezel 3 to rotate freely.

Figures 2 to 5 are isometric views of an exemplary embodiment of the pusher 7 from different perspectives. The pusher 7 has a substantially cylindrical shape. A groove 9 is arranged on a lateral surface 8 of the handle 7 . In a first area, the groove 9 has a first depth. The first area of the groove 9 comprises a tangential section 10. This tangential section 10 is at right angles to a longitudinal axis L of the pusher 7. Furthermore, the groove 9 has a second area with a first axial section 11 of the groove. The first axial section 11 is aligned parallel to the longitudinal axis L of the pusher 7 . The depth of the groove increases in the second region to a second depth that is greater than the first depth. The increase in depth can be seen particularly well in FIG. The first axial portion 11 points from the tangential portion towards a second end 15 of the pusher. The second end 15 of the pusher 7 is arranged inside the watch case 1 or the case ring 2 . At a first end 14 of the pusher 7, which is opposite the second end 15, a head 13 is arranged with a knurl. The first end 14 of the pusher 7 protrudes from the watch case 1 and the casing ring 2, respectively.

The tangential section 10 of the groove 9 extends over approximately 180° around the circumference of the pusher 7 on its lateral surface 8. Opposite the first axial section 11 of the groove 9 (easily visible in FIG. 5) is a second axial section 12 arranged. The second axial section 12 belongs to the first area of the groove 9 and has the first depth. The second axial section 12 also points in the direction of the second end 15 of the pusher 7, but is significantly shorter than the first axial section 11. The pusher 7 has a cavity 28 inside.

6 shows a detailed view of the watch case 1 according to FIG. 1 in the area of the pusher 7 as a sectional view. This figure shows other components of the watch case 1 that are not visible in FIG. In order to ensure the tightness of the watch case, a sealing ring 23 is arranged between the base plate 17 and the caseband 2 . The base plate 17 is connected to the housing ring 2 via a corresponding thread 29 . The pusher 7 is arranged in a radial bore 30 of the housing ring 2 . The radial bore 30 is designed as a blind hole. The pusher 7 is rotatable about its longitudinal axis L and is mounted linearly movable along this longitudinal axis L within the radial bore 30 . The longitudinal axis L of the pusher 7 coincides with the longitudinal axis of the radial bore 30 . So that the pusher 7 does not fall out of the watch case 1 or the case ring 2, it is secured by means of a retaining screw 21 which is screwed into a blind hole 27 which is located within the radial bore 30. The head of the retaining screw 21 cooperates with a peripheral stop 25 located within the cavity 28 of the pusher. By this arrangement, the way that the pusher 7 can be moved along the axis A is limited at the same time. In the head 13 of the pusher 7, a locking screw 22 is also screwed, which closes the cavity 28 to the outside. This configuration allows the push-button 7 to be inserted in the radial bore 30 of the caseband 2 and to be fixed by means of the retaining screw 21.

Within a bore 26 of the housing ring 2, an actuating body 18, which is present as a ball in the embodiment shown, is arranged. The actuating body 18 is also accommodated in the groove 9 of the pusher 7 and can be moved within the groove 9 by rotating the pusher 7 about its longitudinal axis L and by linearly moving the pusher 7 along the longitudinal axis L. FIG. 6 shows the situation in which the actuating body 18 is in the second axial section 12 of the groove, that is to say in the first region thereof, with the pusher 7 thus being in a first position. The first axial section 11 opposite the second axial section 12 is clearly visible. The actuating body 18 interacts with a structure 19 of the steady rest 3 in order to secure it against a rotary movement (see FIG. 9). The bezel 3 is thus locked. The pusher 7 is prestressed along the longitudinal axis by the compression spring 20 in a direction pointing away from the movement 1 . As a result, the actuating body 18 remains in the second axial section 12. The compression spring 20 acts on the peripheral stop 25.

shows the situation after the pusher 7 has been moved along the longitudinal axis L towards the center of the watch case 2 and rotated slightly about the longitudinal axis L. The actuating body 18 is located in the tangential section 10, but due to the first depth of the groove 9 remaining constant in the first region of the groove 9, it still interacts with the structure 19 of the bezel 3, so that the latter is secured against rotational movement.

shows the situation in which the actuating body 18 is in the first axial portion 11 of the second area of the groove 9 and thus in the second area. When the first axial section 11 is reached, the pusher 7 is moved outwards away from the center of the clockwork 1 along its longitudinal axis L due to the pretensioning generated by the compression spring 20 . As a result, the actuating body 18 slides in the first axial section 11, so that the actuating body 18 is at a position within the groove 9 which has the second depth. A distance between the structure 19 of the bezel 3 and the bottom of the groove 9 is increased, so that the actuating body 18 can be moved along a radial axis R away from the structure 19 . As a result, the bezel 3 is no longer secured against a rotary movement and can be rotated freely. This figure also shows the interaction of the peripheral stop 25 with the head of the retaining screw 21 in order to limit the movement of the pusher 7 along the longitudinal axis L.

9 shows an exemplary embodiment of a bezel 3 from below in an isometric view. The structure 19 with which the actuating body 18 interacts is clearly visible. The structure 19 has a plurality of teeth, with the actuating body 18 engaging a space between two adjacent teeth to secure the bezel 3 against rotation.

Claims (14)

1. Watch case with a rotatably mounted bezel and a mechanism for locking the bezel, which has a pusher that is linearly movable along a longitudinal axis and rotatably mounted about the longitudinal axis, characterized in that the pusher has a groove for receiving an actuating body, which is on a lateral surface of the pusher and which has a first region with a first depth of the groove, the first region comprising a tangential section and a second region having a first axial section, the groove in the first axial section at least partially having a second depth which is greater than the first depth, and characterized in that the actuating body is in a first position of the pusher in the first region of the groove and cooperates with a structure of the bezel to secure the bezel against rotation, the Actuating body in a second Position of the pusher is in the first axial portion of the groove with the second depth, so that due to the greater depth of the groove of the actuating body does not interact with the structure of the bezel and the bezel is freely rotatable. 2. Watch case according to claim 1, characterized in that the actuating body is a ball. 3. Watch case according to one of claims 1 or 2, characterized in that the tangential section extends over 160° to 200°, in particular over 180°, of the circumference of the lateral surface of the pusher. 4. Watch case according to one of Claims 1 to 3, characterized in that the groove has a second axial section in the first region, the operating body being in the second axial section when the push-piece is in the first position. 5. Watch case according to claim 4, characterized in that the tangential section of the groove is located between the first tangential section and the second tangential section. 6. Watch case according to one of Claims 1 to 5, characterized in that the first axial section and optionally the second axial section are directed away from the tangential section in the direction of the center of the watch case. 7. Watch case according to one of claims 1 to 6, characterized in that the watch case has a spring which biases the pusher in a first direction which is directed away from the center of the watch case. 8. Watch case according to one of claims 1 to 7, characterized in that in the first axial section the depth of the groove increases steadily from the first depth to the second depth. 9. Watch case according to one of claims 1 to 8, characterized in that the pusher is arranged at the 10 o'clock position of the watch case. 10. Watch case according to one of claims 1 to 9, characterized in that the bezel can only be rotated in one direction of rotation, in particular counterclockwise. 11. Watch with a watch case according to one of claims 1 to 10. 12. Pusher for a watch case according to one of claims 1 to 11, comprising a cylindrical base body with a lateral surface, characterized in that a groove is arranged on the lateral surface, which has a first region with a first depth of the groove, the first The area comprises a tangential section and a second area which has a first axial section, the groove in the first axial section at least partially having a second depth which is greater than the first depth. 13. Handle according to claim 12, characterized in that the tangential section extends over 160° to 200°, in particular over 180°, of the circumference of the lateral surface of the handle. 14. Handle according to one of claims 12 or 13, characterized in that the groove has a second axial section in the first region, the tangential section of the groove being located between the first tangential section and the second tangential section.