Classifications

• • G—PHYSICS
  • G04—HOROLOGY
  • G04B—MECHANICALLY-DRIVEN CLOCKS OR WATCHES; MECHANICAL PARTS OF CLOCKS OR WATCHES IN GENERAL; TIME PIECES USING THE POSITION OF THE SUN, MOON OR STARS
  • G04B19/00—Indicating the time by visual means
  • G04B19/04—Hands; Discs with a single mark or the like
  • G04B19/046—Indicating by means of a disc with a mark or window
• • G—PHYSICS
  • G04—HOROLOGY
  • G04B—MECHANICALLY-DRIVEN CLOCKS OR WATCHES; MECHANICAL PARTS OF CLOCKS OR WATCHES IN GENERAL; TIME PIECES USING THE POSITION OF THE SUN, MOON OR STARS
  • G04B19/00—Indicating the time by visual means
  • G04B19/02—Back-gearing arrangements between gear train and hands
• • G—PHYSICS
  • G04—HOROLOGY
  • G04B—MECHANICALLY-DRIVEN CLOCKS OR WATCHES; MECHANICAL PARTS OF CLOCKS OR WATCHES IN GENERAL; TIME PIECES USING THE POSITION OF THE SUN, MOON OR STARS
  • G04B19/00—Indicating the time by visual means
  • G04B19/06—Dials
• • G—PHYSICS
  • G04—HOROLOGY
  • G04B—MECHANICALLY-DRIVEN CLOCKS OR WATCHES; MECHANICAL PARTS OF CLOCKS OR WATCHES IN GENERAL; TIME PIECES USING THE POSITION OF THE SUN, MOON OR STARS
  • G04B19/00—Indicating the time by visual means
  • G04B19/20—Indicating by numbered bands, drums, discs, or sheets
  • G04B19/202—Indicating by numbered bands, drums, discs, or sheets by means of turning discs

Definitions

• Dial module of a watch and watch provided with a dial module
• the present invention relates to a dial module for a clock, more particularly a dial module provided with several indexes which move on and opposite a time scale on a dial and which are driven by the mechanism of the clock.
• a first category is that of the classic clock equipped with a dial and pointers shaped needles which rotate around an axis under the effect of the clock mechanism.
• a second category, less known, is that of the clock equipped with disks or rotating rings provided with an inscription.
• the discs or rings are placed directly on the drive axes of the clock mechanism and they replace the indexes.
• On the rings are affixed the numbers that correspond to the time function of the ring, namely the numbers 1 to 12 for a ring of hours, 1 to 60 for a ring of minutes and a ring of seconds.
• a reference or a fixed frame on the clock indicates the reading marks or lines, the numbers being on the outermost fixed ring.
• the first category of classical clocks with index and dial has the advantage of being able to rely, in collective thought, on a reading reflex that is almost archetypal.
• Our cognitive processes are such that it is enough to take a look to know the time without having to read for it in detail the figures to which the indexes point.
• a disadvantage of this category is that it mechanically implies that the indication of the time is structured in layers, each index being in another plane to avoid intersections between the indexes.
• the indexes overlap each other in certain positions, or other information, such as date information, may overlap.
• Another disadvantage of such a layered structure is that, as a result, a parallax error occurs during the reading of the time. So that a different time is read according to the viewing angle under which the time is read. The time read is therefore correct only when the time is read from a viewing direction perpendicular to the dial.
• the second category less known, has the advantage that the rings or discs do not overlap, at least when they have been arranged on the same plane.
• the intrinsic disadvantages of this category are that the user is obliged, when he wants to read the time, to read the numbers carefully to know what time it is. To this is added the fact that the figures, because of the geometric structure in rings, have a limited size. The poor ergonomics of reading this category is an important explanation for its small market share.
• the present invention aims to provide a solution for at least one of the aforementioned drawbacks or for another disadvantage.
• the invention relates to a dial module for clock. More particularly, a dial module provided with several indexes that can rotate about an axis, facing a time scale, on a concentrically arranged dial, where the axes of the indexes can be driven by the mechanism of the clock.
• the dial module consists of a housing; at least two separate indexes, respectively a first and a second index, whose axes have been arranged at a radial distance from each other, where each index has been provided with its own separate concentric dial and where at least the second index, together with its axis and its dial, is movable relative to the other second index.
• the two indexes never overlap and the movable dial (s) always retain a fixed orientation relative to the case, where the upper visible portion of the indexes and dials has been arranged. on a single continuous surface.
• the second index has been arranged with its dial inside the circle of gyration of the first index. So that the dial module can be made compact, which is certainly necessary for wristwatches and clocks, while still allowing to have a long index.
• a practical embodiment is characterized by the fact that the first index has been made as an index symbol on a disc which can rotate inside an annular dial and that the dial of the second index has been housed, of to be able to turn, in a bearing of this disc, where the aforementioned disc of first index and the dial of the second index, which is housed in a bearing, are driven by the mechanism of the clock at the same speed of rotation, nevertheless in opposite directions, so that the dial of the second index still retains, during the rotation, the same fixed position relative to the housing.
• the second index moves with its dial in synchronism with the first index, interference or overlap can never occur between the two indexes.
• this embodiment can be achieved in a relatively simple manner by means of gears.
• the dial of the second index may have been made as a ring housed in a bearing of the disk of the first index and the second index may be made as an index symbol on a disk housed so as to be able to rotate. , in a bearing of the second annular dial mentioned above, or vice versa.
• the upper visible band of the dial module can be made completely flat or in a continuous curved surface where the indexes and dials have been arranged in a single continuous surface or on the face of the curved surface.
• the dial module may have been constructed as a module that may be grafted or integrated into the mechanism of a conventional clock with one or more primary central drive shafts and / or one or more secondary drive shafts which have been mounted eccentrically with respect to the aforementioned primary axes, where, for this purpose, the indexes and the dials can for example be driven by means of one or more gears.
• This has the advantage of being able to use existing clock mechanisms, although it has not been excluded that the gear drive is integrated in a clock mechanism developed for this purpose.
• the invention also relates to a clock that contains a dial module according to the invention.
• FIG. 1 schematically and in plan view, a dial module according to the invention
• FIG. 2 shows the dial module of FIG. 1 at another time
• FIG. 3 represents a view like that of FIG. 1, but where the visible part of FIG. 1 was made partially transparent to show the underlying structure;
• FIG. 4 is a section along the line IV-IV of FIG. 3;
• FIG. 5 shows in perspective the gear which has been designated F5 in FIG. 3;
• FIG. 5 shows two alternative embodiments of a gear, as shown in FIG. 5.
• FIG. 1 has been illustrated an example of a dial module 1 according to the invention for a clock, with, in this case, two indexes, for example a first index 2 which represents the minutes and a second index 3 which represents the hours .
• These indexes 2 and 3 are each mounted separately on an axis about which they can rotate, respectively the axes 4 and 5, which have been arranged at a radial distance from one another and can rotate each separately with respect to a clean dial, respectively 6 and 7, which has been arranged concentrically around the axis 4-5 of the relevant index 2-3 and which has been provided.
• an appropriate time scale or other indication for example a time scale 8 for the hours and a time scale 9 for the minutes.
• the dial 6 of the first index 2 is a fixed dial which is part of the housing 10 of the dial module 1 or the clock and which has been made as an outer ring which is coaxial with the axis 4 .
• the first index 2 has also been made as an index symbol 2A on a disk 2B which can rotate coaxially inside the abovementioned annular dial 6 about an axis X-X 'which passes through the aforementioned axis 4.
• the dial 7 of the second index 3 has been rotatably housed in a bearing located in a round opening 11 in the disk 2B of the first index 2 and can rotate around an axis YY 'which follows the movement rotation of the disk 2B about the axis XX 'synchronously.
• the axis YY ' has also been placed, for example, on the indication axis of the first index 2 which, in the example, extends in the direction of the length of the index symbol 2B, although it is not strictly necessary.
• the dial 7 of the second index has also been made as a ring, while the second index 3 has it has also been realized as an index symbol 3A on a second disk 3B which has been rotatably housed in a bearing located in the second annular dial 7 mentioned above.
• the indexes 2 and 3 and the dial 7 are driven by the mechanism of the clock, the dial 7 of the second index 3 being driven about its axis YY 'at a speed of rotation which is equal to that of the first index 2, but in the opposite direction, so that the dial 7 of the second index 3 still retains, during rotation, the same fixed orientation relative to the housing 10.
• the time scale 9 always maintains a fixed orientation as in a conventional clock where the dial 6 is fixed to the housing and thus also maintains a fixed orientation with respect to this housing 10.
• the indexes 2 and 3 are driven by the clock mechanism to indicate, as in a conventional clock, in the known manner, hours and minutes or other information with respect to a time scale.
• the dial module 1 has been shown at 12 o'clock, while in FIG. 2, the dial has been shown at a later time corresponding to approximately eight hours twenty minutes, where it is important to note that the axis 5 of the hour hand 3 and its dial 7 have rotated in synchronism with the minute hand 2 around the XX 'axis.
• This dial 7 of the hour hand 3 having however always kept the same orientation.
• the operation is therefore based on an indication of time with the indexes 2 and 3 which rotate like the indexes of a conventional clock.
• the indexes 2 and 3 refer to a dial 6 and 7 which is not animated with a relative rotational movement. This allows a reading "unconscious” as is the case for classical clocks. By this, we mean that the cognitive reading by an ordinary user allows him to deduce the time by means of the angular position of the indexes without having to read to which digit or symbol of the time scale 8 or 9 the indexes 2 and 3 are oriented.
• any figures or other indications maintain a fixed orientation, so they remain always readable without having to be read backwards or sideways.
• the drive of the dial module 1 is effected by means of a gear 12 which is in turn driven by the primary axis and / or the secondary drive axes of the mechanism of a clock which, for the sake of simplicity, has not been shown in the figures.
• Figs. 3 to 5 has been shown an example of such a gear that can be grafted onto the mechanism of a conventional clock with a central drive shaft which drives the disk 2B of the first index 2 via the axis 4 above.
• the gear mechanism 12 is composed of a stationary central gear 13 which has been fixed on the housing 10 and whose axial line coincides with the axial line X-X '.
• the toothed wheel 13 meshes with a toothed wheel 14 which can rotate freely about an axis 15 of axial line Z-Z 'which has been fixed to the disk 2B of the index 2.
• This latter gear 14 meshes again with a toothed wheel 16 which has been mounted coaxially on the annular dial 7 of the second index 3 and which drives this dial 7.
• a coaxial toothed wheel 17 which meshes with a toothed wheel 18 which has been fixed to the disk 3B of the second index 3 and whose axis coincides with the axial line Y-Y '.
• This toothed wheel 18 has been housed in a bearing located on an axis 19 which has been fixedly attached to the disk 2B of the first index 2.
• the dial 7 of the second index 3 will therefore always maintain the same orientation relative to the housing 10.
• the second index 3 is driven by the rotation of the toothed wheel 17, which rotates in synchronism with the toothed wheel 14 and which drives the toothed wheel 18 of the disk 3B of the second index 3.
• the second index 3 will rotate inside its dial 7 like an index of a conventional clock.
• the continuous surface is, in a way, an almost closed surface. At least, the tiny game between indexes and dials near.
• the clock is therefore also substantially dust-tight and can be easily made completely dust-tight by placing seams between indexes and mobile dials.
• indexes and dials are not in a plane, but rather, with the same advantages, on a hollow or curved surface and continuously bent, where the axes XX ', YY' and ZZ ' do not necessarily have to be parallel to each other.
• a third index such as a second hand or another index, which can then, for example, have been integrated in the disk 2B or 3B of first or second index 2 or 3 and this, for example, in a manner similar to that of which the second index 2 and its dial 7, in the embodiment described above, have been integrated in the disk 2B of the first index 2.
• dial module in the example of FIGS. 3 to 5, is driven only by a single drive shaft 4. This makes it easier and more compact the mechanism of the clock that is used for training.
• dial module itself is driven only by a limited number of gears.
• the gears in the example shown, having been composed of only two stages of toothed wheels, which makes it possible to produce a compact dial module in height with respect to known dial modules, in which at least three stages of gears are used.
• a direct drive is also possible, where, for driving indexes and dials, two or more primary central drive shafts of a conventional clock are used, and where, consequently, the gear 12 has been geared down into elements each of which is driven by a drive shaft separate from the clock mechanism.
• FIG. 6 An example of such a direct drive has been shown in FIG. 6 in the case where two primary drive axes of the clock mechanism are used.
• the toothed wheel R is directly mounted on a first of the central primary axes in replacement of an index, for example on a central drive shaft for the seconds.
• the gearwheel 0 is stationary and has a function similar to that of the gearwheel 13 in the indirect drive described above.
• the axial lines L, M and N revolve around X-X '.
• the bearings of L, M and N have been fixed to the disk 2B of the first index 2, which has X-X 'as an axial line.
• the disk 2B is mounted directly on the second primary drive axis of the clock mechanism or is driven via a secondary axis.
• the gearwheels 0, P and Q are integral with each other. This means that when 0 has as many teeth as Q, during a translation of L and N around X-X ', the relative angular displacement of Q with respect to 0 will be zero.
• Q is directly integral with the annular dial 7, via a common axis which rotates about the axial line N. This means that the annular dial 7 will maintain a fixed orientation relative to the housing 10 during a translation of N around A, if 0 and Q have the same number of teeth and are integral with each other via P.
• the rotation of the first index 2 around the axis N will be initiated by R via S and T.
• the gear wheels S and T are fixedly secured to each other via an axis which rotates around M or have been integrated in a single toothed wheel ST.
• the ratio between the toothed wheels U and T or S and T must cause the relative angular displacement between R and U to be zero. If the toothed wheel R has as many teeth as the toothed wheel U and if the toothed wheel S has a ratio 60/59 with respect to T, a translation of M and N around XX 'will produce a relative angular displacement of zero between R and U. As a result, the angular displacement of R will be equal to that of U.
• a drive is also possible via one or more secondary drive axes of a conventional clock mounted eccentrically, where these secondary axes, in a conventional clock, are for example used for a small seconds hand mounted eccentrically as is often used when the clock has been equipped with a stopwatch function, or are used for other functions as the indication of the day, the moon phase, the operating reserve and other such indications.
• FIG. 7 is a variant of a direct drive via a secondary axis.
• This variant consists of a gear located between the fixed clock and the disk 2B of the first index 2, by means of a combination of the toothed wheels W, R, V and U.
• the toothed wheel R is firmly attached to V, and V and R can rotate together freely about their axis XX '.
• V is in turn coupled to the toothed wheel W, which has been fixed. on a secondary axis Y of the clock mechanism.
• W replaces the function which, on the traditional clock, is driven by the axis concerned. In this way, the angular displacement is transmitted from W to U via R and V.
• the mutual ratios between the number of teeth of R and U must resume the rotation of N around A. Thanks to the three gears described above, all the traditional clocks can virtually serve as a basis for driving a dial module 1 according to the invention.
• time scale must be interpreted in a broad sense and that it also includes, for example, an indication of the phases of the Moon, the operating reserve or other indications.
• a dial module according to the invention and a clock equipped with such a module can be made in all kinds of shapes and dimensions without departing from the scope of the invention.

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Citations (3)

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• 2009
  • 2009-12-11 BE BE2009/0789A patent/BE1019110A5/nl active
• 2010
  • 2010-12-10 RU RU2012126872/28A patent/RU2537748C2/ru active
  • 2010-12-10 EP EP10810839.0A patent/EP2510406B1/fr active Active
  • 2010-12-10 US US13/515,055 patent/US8743664B2/en active Active
  • 2010-12-10 ES ES10810839.0T patent/ES2633488T3/es active Active
  • 2010-12-10 WO PCT/BE2010/000082 patent/WO2011069218A1/fr active Application Filing
  • 2010-12-10 BR BR112012013966A patent/BR112012013966B1/pt not_active IP Right Cessation
  • 2010-12-10 JP JP2012542318A patent/JP5871811B2/ja active Active
  • 2010-12-10 CN CN201080056285.0A patent/CN102939569B/zh active Active

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