DE112011103746T5 - Timing indicator mechanism comprising a radially rotatable pointer member - Google Patents

Abstract

A mechanism for displaying marks (R) disposed chronologically, at least partially around a major axis (3), in a direction along a substantially planar path. A supporting element (15) of a pointer element (5), which is driven in rotation by at least one pointer wheel (17), rotates about the said main axis (3). The latter is connected to reduction means (20) for driving a cam disc (30) at a speed different from that of the support member (15), the non-circular profile of the cam disc (30) being read by a cam follower (35), which is attached to the pointer member (5). This organ (5) is arranged radially displaceable by a guide means 825) on its support element (15).

Description

The present invention relates to a mechanism for displaying markings, which is used in particular for equipping the display of a timepiece, preferably a wristwatch. This mechanism has the peculiarity of comprising a radially rotatable pointer member, which makes it possible to successively display a plurality of marks on the dial, which are arranged at different distances from the center thereof.

The display of calendar events, such as the date, conventionally takes place via a disk on the outer edge on which the daily data are arranged. So that the latter can appear as large as possible and are therefore easy to read, one usually uses as a support element a disc with the almost largest diameter, which can just be accommodated in this watch case. The date of day may be indicated by a central pointer, or more generally in a display window most commonly located at three o'clock on the dial. However, the maximum size of the numbers forming the current date remains limited to the surface of a band divided into 31 equal parts on the outer edge of the disc serving as a support member.

Although rarer than the daily data, the display of the days of the week or the months of the year are often cut off or displayed very small, since a larger number of letters of the alphabet must be arranged on the outer edge of the support element.

Of course, this problem is even more present with small timepieces, especially with pocket watches or wristwatches.

However, regardless of the size of the dial, further problems may be associated with reading marks displayed on the dial. For example, mention is made of the use of an indices distributed regularly on the edge area, each of which being associated with a number pair indicating the twenty-four hours of the day. Thus, all hourly data separated by an interval of twelve hours (for example, ten o'clock and twenty-two o'clock) are displayed by the same index. Although everyone naturally distinguishes day and night, there is no clue as to which of the two numbers should be read except for this biological sensibility. To solve this problem, it is known to add a supplementary day / night display to clarify which number should be read.

Another way to display the twenty-four hour schedule of the day is to divide the display of the dial into 24 parts and assign to each a mark corresponding to an hour. The main drawback of such a display is that everyone is used to reading a conventional watch with hands. In this case, it is almost impossible to read the time quickly and without a considerable effort, since the distribution of the first twelve hour parts are not distributed to 360 ° but on the first half of the dial.

The aim of the present invention is to at least partially solve the above-mentioned problems by providing a display mechanism that allows to directly and without detour display an index or a tag in a sequence of multiple tags, preferably, but not exclusively, more than a circumference of the dial. In the latter case, the markers could be arranged in a spiral shape such that a plurality of marks would be arranged in the same even very acute angle range, with at least the apex of the angle being near the center of the spiral.

According to the invention, the mechanism for indicating such markers comprises a pointer member, typically a pointer, capable of radial movement, telescoping-generating expanding / retracting movement, and rotational movement so that each of the markings displayed on the dial face is accurately displayed can be. Preferably, the rotational movement of the pointer member is generated by translation of the same on a support member, wherein the rotation of the latter performs the aforementioned rotational movement.

According to the embodiment of the invention, the rotational movement is generated by a cam disc whose profile is read by a cam follower which is fixedly connected to the pointer member. The rotational movement takes place by connecting the support element of the pointer member with a rotation axis of a pointer wheel. The latter is set to a speed which depends on the one hand on the type and on the other hand on the distribution of the time marks on the dial. It is self-evident that the speed is different when the marks indicate the twenty-four hours of a day or the days of a month. It is also conceivable that if such markers are arranged along a four-turn spiral at 360 °, the speed would be twice as high as if the same marks were distributed along a spiral of only two turns to 360 °.

The ratio of the radial velocity of movement of the pointer member and its rotational speed depends on two parameters. The first parameter is related to the shape of the cam disk profile. More precisely, and in the event that this cam has a spiral profile, this parameter depends directly on the tangential polar angle, which at one point forms the intersection of the tangent of that profile with the straight line, the tangent point with the center of the curve combines. The larger the angle compared to a right angle, the clearer is the radial locomotion. In other words, by placing the straight line passing through the center of the curve in a vertical plane, the range of radial travel would be dependent on the slope of the aforementioned tangent. It should be noted, therefore, that the rate of radial travel of a pointer member which is to follow a coiled, tightly wound helix would not be the same velocity as if this helix were somewhat further wound, for the same number of revolutions.

In simple terms, the second parameter, taken in isolation, depends on the difference between the rotational speed of the cam and the rotational speed of the pointer. According to the invention, the latter speed is determined by the rotation of the pointer wheel, at least it contributes to this. More specifically, this speed ratio is generated by a Übersetzungsrad which is set between the pointer wheel and a so-called cam wheel, which is fixedly connected to the cam. This difference in speed results in a sliding of the cam follower (connected to the pointer member) on the cam disc.

Advantageously, the device according to the invention successively allows a plurality of markings and / or contiguous indices spaced differently from the pivot point of the pointer member to be displayed accurately and avoiding any ambiguity in reading, by directly indicating the mark or the particular index. By virtue of such a display mechanism, it is possible to utilize a larger area on the dial of a clock to place said markers / indices at different pitches relative to the center of rotation of the pointer. Advantageously, thereby the markers / indices themselves can also have larger dimensions in order to be more readable.

Typically, it is possible to double the size of the daily data by placing it on two levels around the dial, for example, by spreading it on two spiral arms of a spiral winding twice around the dial. The use of a larger surface also allows indexes not to be cut off, such as the days of the week or the months of the year, which the mechanism is able to display clearly and without reading uncertainty. By distributing such indices at different distances from the fulcrum of the pointer, it is advantageously possible to write them with all the letters.

As an example, the present invention, thanks to its telescopic effect mechanism and hand, allows the complete display of long astronomical cycles, such as the meton cycle or metonic cycle, where every 19 years the data of the phases of the moon are repeated. Also worth mentioning is the possibility of displaying the Saros cycle used to predict lunar and solar eclipses, with the duration of a whole cycle being 18 years, 11 days and 8 hours.

Overall, it should be noted that the inventive mechanism allows the display of markings and / or entries without affecting their number, size, quality or readability, by such a concentration of these indices on a dial that the latter could also be of lesser size, especially the size of a dial of a wristwatch.

Further advantages and specifications will become apparent from the following description of the drawings, which refers to a preferred embodiment and which illustrates, without being limiting, schematically and by way of example the attached figures:

The 1a and 1b Fig. 12 are schematic plan views showing two different states of the display which can be obtained by the mechanism according to the invention.

2 is a perspective view of the subject invention seen from above.

3 is a bottom view of the subject invention 2 ,

4 is a sectional view taken along the line IV-IV 3 ,

5 is a sectional view taken along the line VV 3 ,

6 is a schematic partial view from above illustrating the kinematics of the mechanism according to the invention.

The 1a and 1b provide the time-marker R display system of the mechanism according to the invention 1 in two different positions.

Such markers R, shown as an example in these figures, are thirty-one to represent the daily data and are shown as curved areas which, when placed adjacent to each other, together form an Archimedean spiral. Since the arrangement of the marks R is by no means limited to the representation of such a spiral shown, it should be said in general that these marks are chronological and at least partially about a major axis 3 of the mechanism 1 are arranged, and that their arrangement takes place only in a direction of rotation along a mainly flat path, either non-circular or circular and offset from the main axis 3 is.

The marks R are by a pointer organ 5 displayed, shown here as a pointer, which by the mechanism 1 in rotation and radial translation relative to the major axis 3 is driven. As with a clock mechanism where the hands point to the hour and minute marks to indicate the time, the mechanism is 1 also designed so that a perfect match between the pointer organ 5 and the nature of the marks R, which is to indicate this successively.

1a provides an indication of the mechanism 1 at a time t _1. In this first position, it can be seen that the pointer organ 5 pointing to the nineteenth day of the month, more precisely said to the second part of this day. In comparison shows 2 a similar representation at a second time t ₂ , which is after the first time; It should be noted here that the pointer organ is currently pointing to the twenty-fourth day of the month, especially the end of that day. Between times t ₁ and t ₂ , the pointer has sequentially displayed all days between the two aforementioned dates and, to do so, has performed a double movement, namely a clockwise rotation and at the same time a radial translation relative to the main axis 3 such that one end of the pointer has moved, with respect to its tip, away from the axis by a distance corresponding to a spiral step, ie a distance equal to the distance between two adjacent spiral arms.

The following description will describe in more detail the mechanism that enables such a display.

The 2 and 3 set the mechanism 1 simplified, without the marks R and their display is, for a perspective view from above and the corresponding view from below. The 4 and 5 correspond vertical sectional views, corresponding to the lines IV-IV and VV, as in 3 shown. As already in 2 aptly shown, becomes the pointer organ 5 by a support element 15 held in the form of a platform. This comprises a slide rail comprising two pairs of rollers, on both sides of the pointer member 5 are arranged and a guide means 25 form.

How better in 4 shown, the piece element 15 through one on the main axis 3 mounted sleeve 16 by means of at least one pointer wheel 17 driven to a rotational movement, due to its connection to the pointer member 5 over the support element 25 so called. This pointer wheel is itself by a drive means 18 set in rotation, providing the necessary energy to turn the mechanism 1 supplies.

Related to 3 and the sectional view in 4 you notice that the pointer wheel 17 with a movable reduction 20 , more specifically with one on a wheel 21 attached gear 22 connected is. The wheel 21 and the pinion 22 of the movable transmission part 20 are concentric to the rotation axis 2 , This movable transmission part 20 is meant to be a cam disc 30 to turn their non-circular profile in the 2 and 3 is shown at a speed different from that of the support element 25 different.

The profile of the cam is from a cam follower 35 read, which is shown in the form of a pin and which serves as a reading finger of the cam. This cam follower 35 is fixed to the pointer organ 5 and is located approximately on a third of this organ, more precisely on the third of the end, which is to indicate the marks R.

The pointer organ 5 on which the cam follower is mounted is subject to the force of an elastic return means 26 to ensure permanent contact between the cam follower 35 and the cam disk 30 to effect. This return means 26 is against a restraint 27 attached, firmly with the pointer organ 5 connected is. Its ends are on the support element 15 with a fastening means, for example with screws 28 attached. According to a preferred embodiment, the retaining means 27 advantageously by the free end of the cam follower 25 serving pin. As shown in the attached figures, the elastic return means 26 formed by at least one spring, in particular by a spring, whose constant changes only slightly over time, especially over several decades.

According to a preferred embodiment shown in the attached figures, the gear is 22 of the movable transmission part 20 designed so that it is the cam 30 via the interposition of a cam wheel attached to the cam 23 set in rotation. Advantageously, the cam wheel 23 and the pointer wheel 17 concentric with each other around the ring piece 16 arranged and thus have the main axis 3 as a rotation axis. It should be noted that the cam wheel 23 without further connection with this axis, idling on the sleeve 16 is mounted.

As a variant, it would be possible, the cam wheel 23 to turn another axis to reduce the thickness of the mechanism and thus created space to the kinematic chain of the mechanism 1 expand.

Referring to 6 , which represents the kinematics of the mechanism according to a partial schematic view from below, is the profile of the cam disc 30 designed so that the pointer organ 5 during the reading of the profile, by means of the cam follower 35 between a starting point 31 and an endpoint 32 of the profile constant from the main axis 3 away.

Nevertheless, the profile of the cam can 30 also be designed so that the pointer organ 5 during its angular motion a series of distances and approximations relative to the major axis 3 performs.

The function of the mechanism described above will now be described with reference to FIG 4 and 5 described. The pointer wheel 17 , which by the movable drive element 18 driven, drives itself, thanks to the kinematically connected to these two organs sleeve 16 , the support element 15 at. According to the preferred embodiment, the tube or the sleeve 16 one-sided on the pointer wheel 17 riveted and on the other hand on the support element 15 of the pointer organ 5 pressed.

The pointer wheel 17 drives over the wheel 21 the diverting movable reduction 20 at. The gear 22 this part then drives the cam wheel 23 which free around the sleeve 16 rotates. This cam wheel 23 is about a screw 33 ( 5 and 6 ) on the cam disc 30 attached, which also allows a fine adjustment of the position of the cam disc on the cam wheel. As in 2 shown, the pointer organ 5 on his support element 15 through the pairs of roles 25 held. These allow a translational movement in one direction, the longitudinal axis of the pointer member 5 equivalent. This axial translational movement, perpendicular to the main axis 3 , is subject to an opposing force by the elastic return means 26 is effected, which transmits a backward movement to the pointer member by relying on the latter. This action creates a permanent contact between the cam follower 35 and the flank of the cam disk 30 ,

That on the support element 15 attached pointer organ 5 becomes in accordance with a first rotational movement with one of the rotational speed of the pointer wheel 17 driven at the appropriate speed. At the same time the pointer organ 5 also in accordance with a second radial translational movement by the rotational movement of the cam disc on the cam follower 35 driven. The range of this radial movement thus depends directly on the profile shape of the cam and its rotational speed. The latter is determined in a ratio depending on the speed of the pointer wheel 17 , through the movable reduction 20 , in particular by the ratio of the diameter of the wheel 21 and the gear 22 ,

As intended for its main use, the mechanism is 1 so dimensioned that the gear ratio between the on the pointer organ 5 attached pointer wheel 17 and on the cam 30 fixed movable part 23 the number of revolutions of the pointer organ 5 around the main axis 3 certainly.

For example, if said ratio is equal to 0.8, the pointer organ will guide 5 five turns while the cam only makes one revolution. In other words, one can conclude that the pointer organ 5 with a 20% higher speed than the cam plate moves. This results in a sliding of the cam follower during the rotational movement of the pointer member 35 on the flank of the cam disc. In this way, and according to the values given here by way of example, the indicator member must make five turns so that the cam follower itself runs the entire distance of the edge length of the cam disc, ie the distance between the starting point 31 and the endpoint 32 the cam disk profile ( 6 ). As soon as the cam follower reaches the end point 32 has reached, the pointer organ returns 5 under the action of the elastic return means 26 back to its starting position, the positioning of the cam follower at the starting point 31 equivalent. This immediate return is due to the property of the cam disk 30 which is an instant jump cam.

To avoid any damage to the mechanism if it were turned in the opposite direction of the normal direction of rotation of the pointer additionally provided that the latter comprises a safety mechanism that allows the cam follower 35 allows to prevent the path defined by the cam flank from being cut off and a second path 36 ( 6 ), which is an abbreviation to the starting point 31 represents.

For this purpose and as in the 2 and 6 is shown, the cam follower with a flexible element 40 which gives it a bending degree of freedom in a substantially perpendicular to the plane in which the in the 1a and 1b shown marks R are arranged lying direction. According to the preferred embodiment, the recess is obtained 40 by placing a pointer organ 5 continuous slot 41 will be produced. This slot 41 runs around the cam follower and then extends in the vicinity of the same in the direction of the outside of the edge of the pointer member 5 ,

In addition, the cam disk includes 30 at least one groove 34 . 34 ' , a so-called safety groove, which is the cam follower 35 after taking it through an inhibiting organ 37 was brought in the aforementioned, substantially vertical direction, so that the cam follower even faster the starting point 31 can reach the cam disk profile. According to the preferred embodiment, the inhibiting organ 37 simply be formed by a sloping plane.

Overall, the profile of the cam 30 in no way limited to a representation of a constant distance movement of the pointer member or to a linear increase of this removal, as is the case when the markers are arranged along an Archimedean spiral.

By modifying the cam profile, it would also be possible for the pointer to follow a different spiral, especially a logarithmic spiral, also called an equiangular spiral because of its constant polar tangent angle (non-rectangular) or even growth spiral due to its variable slope.

Very generalized and theoretically, the mechanism allows it 1 to display, in a chronological order along a single direction of rotation, any mark according to a polar coordinate system, its starting point on the principal axis 3 centered. The two polar coordinates of such a system, defined by an angle and a distance to this origin, can be achieved by the pointer, thanks to its rotation and axial translation, which allow it to move in combination.

Although the cam profile 30 was presented with a flat even surface, it is also conceivable that this profile could be formed with several layers stepped, so that the pointer organ 5 would exert a leap effect that would periodically manifest itself as a brief acceleration when traversing two adjacent marks R.

As a variant and further with the aim of giving the pointer organ a retracting / expanding effect, it would also be possible to achieve a comparable radial movement through a truly telescopic organ, i. H. it would consist of several interlocking and interlocking elements. In this case, it would be conceivable to omit the support element for the pointer member, the latter could then be arranged, for example, rotating directly around the main axis.

Even if the subject of the present invention also involves the use of a mechanism 1 with an indication of marks R distributed over more than 360 ° on one and the same dial or different planes, it should be noted that the distribution of markings is in no way limited to such a range of values, it may also be a single revolution on the dial, ie comprise a single turntable.

In a particular use, the mechanism of the present invention could also be used to display twenty-four indices or marks corresponding to twenty-four hours a day evenly distributed over two rounds of the dial of a timepiece.

In other embodiments, the mechanism could also be used to display the days of the week, the annual months, or cyclic astronomical events, especially those in which the cycles extend over more than a decade.

Due to the advantage achieved with this mechanism according to the invention in a small space, this mechanism is preferably used in connection with wristwatches. However, it should be noted that the subject matter of the invention is in no way limited to the movement of timepieces, but could also be excellently linked to other types of movement, for example as a stand-alone object.

Claims (17)

Mechanism ( 1 ) for displaying chronologically, at least partially around a major axis ( 3 ) arranged in a direction along a substantially planar path arranged markings (R), characterized in that it is a support element ( 15 ) rotatable about said major axis ( 3 ), drive means ( 17 . 18 ) for this support element ( 15 ), a pointer organ ( 5 ), with the support element ( 15 ) firmly connected guide means ( 25 ) for translation associated with the pointer organ ( 5 ), a movable cam ( 30 ), Reducing agents ( 20 ) for the kinematic connection of the cam disc ( 30 ) with the support element ( 15 ) and elastic return means ( 26 ) connected to the pointer ( 5 ) to keep it constant with the profile of the cam ( 30 ), so that movement of the pointer ( 5 ) from the combination of the relative movements of said support element ( 15 ) and the said cam disc ( 30 ), which are selected such that the pointer ( 5 ) runs said markings (R) in the desired speed. Mechanism according to claim 1, characterized in that the profile of the cam disc ( 30 ) is designed so that the pointer member ( 5 ) from the main axis ( 3 ) while running the entire cycle of said marks (R). Mechanism according to claim 2, characterized in that the profile of the cam disc ( 30 ) is designed so that the removal of the pointer member ( 5 ) linearly increasing. Mechanism according to claim 1, characterized in that the profile of the cam disc ( 30 ) is designed so that the pointer member ( 5 ) during its angular movement a gradual removal and approach in relation to the main axis ( 3 ). Mechanism according to claim 1, characterized in that the reduction means ( 20 ) a first moving part ( 21 ) driven by the drive means ( 17 . 18 ) and coaxial with this first moving part ( 21 ) a second moving part ( 22 ) in contact with the cam disc ( 30 ), preferably by interposing one with the cam ( 30 ) fixedly connected movable part ( 23 ). Mechanism according to claim 5, characterized in that the transmission ratio between the movable part ( 17 ) and the cam connected to the movable part ( 23 ) the number of revolutions of the pointer ( 5 ) around the axis ( 3 ) certainly. Mechanism according to one of claims 1 to 6, characterized in that the two extremities of the cycle described by the cam are connected by an instantaneous jump of the pointer member generating element. Mechanism according to one of claims 1 to 7, characterized in that the elastic return means ( 26 ) consists of at least one spring, one end of which on the support element ( 15 ) is attached and the other end with the pointer member ( 5 ), preferably at a free end ( 27 ) of a cam follower ( 35 ) is applied to the pointer member ( 5 ) in contact with the profile of said cam disc ( 30 ) bring to. Mechanism according to one of claims 1 to 8, characterized in that the guide means ( 25 ) of the pointer ( 5 ) on its supporting element ( 15 ) is a slide rail. Mechanism according to claim 9, characterized in that said slide rail is formed from a plurality of rollers. Mechanism according to claim 1, characterized in that the cam follower ( 35 ) to the pointer ( 5 ) in contact with the profile of said cam disc ( 30 ), with a flexible element ( 40 ) that gives it a degree of freedom to bend in a direction substantially perpendicular to the plane in which the markers are arranged, and that the cam disc ( 30 ) at least one safety groove ( 34 . 34 ' ), which is designed such that the cam follower ( 35 ) engages them as soon as this cam follower in the said, perpendicular to the plane in which the markers are arranged, by an inhibiting element ( 37 ) is moved to enable it to the starting point ( 31 ) of the cam disc ( 30 ) over the branch line ( 36 ) to return. Mechanism according to claim 11, characterized in that via the pointer ( 5 ) a slot ( 41 ) running close to the cam follower ( 35 ) runs around and in the direction of the outer edge of the pointer member ( 5 ) and the recess ( 40 ). Mechanism according to claim 11, characterized in that the inhibiting element ( 37 ) is formed by an inclined plane. Use of the mechanism according to one of the preceding claims for displaying the markings (R) distributed on 360 ° or more on a single dial. Use according to claim 14 for displaying 24 marks (R), corresponding to the 24 hours of a day spread over twice 360 °. Use according to claim 14 for displaying the days of the week, the months of a year or of cyclic astronomical events, in particular with cycles which extend over more than a decade. Use according to one of the preceding claims in conjunction with a wristwatch.

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