This application claims priority from European Patent Application No. 12173916.3 filed Jun. 27, 2012, the entire disclosure of which is incorporated herein by reference.
The present invention concerns a bracelet or wristband with a magnetic clasp comprising permanent magnets and it concerns, in particular, a watch bracelet comprising this type of magnetic clasp.
d of FR Patent No 2 834 622 illustrates a watch bracelet with a magnetic clasp comprising first and second flexible strands, both strands being separable and arranged to overlap each other in the closed position of the bracelet. The bracelet further comprises two magnetic elements; the first bracelet strand includes a first magnetic element which is fixed, whereas the second strand, in the form of a hollow shaft, includes a second magnetic element, called the “moveable element”, which is arranged to slide longitudinally, as a friction tight fit, inside the hollow shaft. When the strands are in the closed position, the two magnetic elements are opposite each other and mutually attract each other. Thus, the two magnetic elements enable the two strands to be secured to each other in the closed position of the bracelet. Moreover, it is possible to adjust the length of the bracelet by sliding the moveable magnetic element inside its hollow shaft. Further, the Patent document teaches that it is possible to adjust the bracelet length simply by sliding one of the strands longitudinally against the other in the closed position of the bracelet. Indeed, provided that the force of attraction exerted by the fixed magnetic element on the moveable magnetic element is sufficient to overcome the friction force, sliding one strand over the other causes the moveable magnetic element to slide inside its hollow sheath.
However, this known solution has certain drawbacks. Indeed, if the force of attraction between the magnetic elements is not sufficient to overcome the friction force, it will be impossible to adjust the bracelet length. Conversely, if the moveable magnetic element slides too easily inside the hollow shaft, the bracelet is liable to be impossible to tighten sufficiently.
It is an object of the present invention to overcome the drawbacks of the prior art that have just been described. The present invention achieves this object by providing a bracelet with a magnetic clasp conforming to the annexed claim 1.
One advantage of the invention is that it is possible to select the length of the bracelet simply by choosing which one of the plurality of second magnetic circuit portions is placed in a superposed position with the first magnetic circuit portion. Further, if none of the second magnetic circuit portions is superposed exactly on the first magnetic circuit portion, the mutual attraction existing between the first magnetic circuit portion and the closest second magnetic circuit portion is normally sufficient to bring said second portion into a superposed position.
Another advantage of the invention is that the use of an entire row of bipolar magnets, instead of a single magnet, enables the contact surfaces of the two end parts to be better secured to each other in the closed position of the bracelet. Further, the presence of a yoke made of soft ferromagnetic alloy in each magnetic circuit portion has the advantage of channelling the magnetic field properly, and thus of further increasing the mutual force of attraction between the first and second magnetic circuit portions.
According to an advantageous variant of the present invention, the length of the ferromagnetic yokes is greater than half the length of the end parts of the bracelet. Owing to this feature, the strap-shaped end parts may be flexible lengthwise yet relatively rigid widthwise. This feature has the advantage of enabling the bracelet both to adopt the shape of a wrist and to ensure proper adherence between the contact surfaces in the closed position of the bracelet.
According to another advantageous variant of the invention, the space between two second magnetic circuit portions is at least equal to three-quarters of the width of one of the second magnetic circuit portions. This feature has the advantage of enabling the bracelet to adopt the shape of the wrist of the person wearing it.
According to an advantageous embodiment of the invention, several first magnetic circuit portions are integrated in the first end part, said first portions being arranged parallel to each other and spaced apart from each other. This multiplication of the magnetic circuit portions proportionally increases the magnetic force of attraction which unites the contact surfaces of the two end parts in the closed position of the bracelet.
According to an advantageous variant of this latter embodiment, the first magnetic circuit portions which are integrated in the first end part are spaced further apart from each other than the second magnetic portions which are integrated in the second end part. Indeed, in the closed position, the first end parts is on the external side of the ring formed by the bracelet, whereas the second end part is on the internal side. In these conditions, it will be clear that the same given angle subtends a longer arc of a circle on the external end part than on the inner end part. The feature whereby the first magnetic circuit portions are spaced further apart from each other than the second magnetic circuit portions thus corrects the overlapping effect of the end parts and ensures that the first and second magnetic circuit portions are properly aligned in the closed position of the bracelet.
According to a preferred embodiment of the latter variant above, the space between the second magnetic circuit portions gradually decreases away from the end of the second end part of the bracelet. Indeed, the further away the second magnetic circuit portions (on which the first magnetic circuit portions are superposed) are from the end of the bracelet, the tighter the bracelet will be, or, in other words the smaller the diameter of the bracelet will be. In these conditions, it will be clear that the tighter the bracelet is, the more necessary it will be to reduce the space between the second magnetic circuit portions in order to correct the overlapping effect of the end parts and to ensure that the first and second magnetic circuit portions are properly aligned in the closed position of the bracelet.
According to another advantageous variant of the aforementioned embodiment, the second magnetic circuit portions each include a row of bipolar magnets arranged between the ferromagnetic yoke of the second portion and the contact surface of the second end part; the directions of polarisation of the magnets of one row are parallel to each other and normal to the contact surface of the second end part. Further, the rows of magnets of the first and second magnetic circuit portions all have the same number of magnets; the magnets are arranged so that the magnets of the first portions are each matched with a magnet of a second portion in the closed position of the bracelet, two matched magnets being superposed and polarised in the same direction. The feature whereby the first and second magnetic circuit portions each include magnets, in the configuration described above, further increases the magnetic force of attraction between the contact surfaces.
According to another advantageous embodiment of the invention, the direction of polarisation of certain magnets of a row is in the opposite direction to the direction of polarisation of the other magnets of the same row. This feature has the advantage of better channelling the magnetic field in the magnetic circuit portions. According to an advantageous variant of this latter embodiment, each magnet in a row of magnets is polarised in the opposite direction to its closest neighbour in the row of magnets. This latter feature has the effect of shortening the path travelled by the magnetic field, and thus of intensifying the magnetic field in immediate proximity to the contact surfaces.
Other features and advantages of the invention will appear upon reading the following description, given solely by way of non-limiting example, with reference to the annexed drawings, in which:
a shows a schematic, perspective view of the wristwatch of
b is a partial cross-section showing in more detail the magnetic clasp of the bracelet of
a is a schematic diagram of the magnetic clasp of a bracelet according to a second embodiment of the invention, and showing, in perspective, the arrangement of the first and second magnetic circuit portions in the closed position of the bracelet.
b is a partial front view of the embodiment of
Referring to
Simultaneously considering now
Referring now to
The numerical values given above for the size of the spaces which separate two second magnetic circuit portions also illustrate the fact that the space between the second magnetic circuit portions preferably gradually decreases away from the end of the second end part 9 of the bracelet. Indeed, the further away the second magnetic circuit portions (on which the first magnetic circuit portions are superposed) are from the end of the bracelet, the tighter the bracelet will be, or, in other words the smaller the diameter of the bracelet will be. In these conditions, it will be clear that the tighter the bracelet is, the more necessary it will be to reduce the space between the second magnetic circuit portions in order to correct the overlapping effect of the end parts and to ensure that the first and second magnetic circuit portions are properly aligned in the closed position of the bracelet.
According to the invention, magnetic circuit portions 11a, 11b, 12a, 12b, 12c, 12d, 12e, 12f all include a soft ferromagnetic alloy yoke (referenced respectively 14, 14b, 16a, 16b, 16c, 16d, 16e and 16f in
Simultaneously considering
Since the magnetic force of attraction decreases with distance, this force is mainly exerted between the first and second magnetic circuit portions closest to each other. As these closest portions are generally substantially superposed, the magnetic force is exerted, above all, perpendicular to the contact surfaces. Thus, the attraction between the magnetic circuit portions has the effect of causing the contact surfaces to adhere strongly to each other. Moreover, it will be clear that the magnetic attraction force also resists any longitudinal sliding of the contact surfaces against each other. This latter feature has the advantage of permitting flat contact surfaces to be used between the bracelet strands, and thus of omitting notches or any other mechanical immobilising means. It can thus be said that the first and second magnetic circuit portions perform the function of “magnetic notches”.
a and 3b are two partial schematic views of the arrangement of first and second magnetic circuit portions which forms the magnetic clasp of a bracelet according to a second embodiment of the invention. The first and second magnetic circuit portions used in this second embodiment may be identical to those used in the first embodiment described above. The difference between the first and second embodiment essentially lies in the use of a larger number of first and second magnetic circuit portions for the second embodiment. As shown in
According to the invention, the first and second magnetic circuit portions 111 and 112 each include a soft ferromagnetic alloy yoke (referenced 114 for the first portions and 116 for the second). In the embodiment described, as in the preceding embodiment, the yokes take the form of small rectangular plates. They may be made for example by cutting a laminated iron-cobalt alloy strip such as those supplied by ArcelorMittal® under the name AFK502. In the example described, the length of the yokes is 25.75 mm, the width is 4 mm and thickness is 0.5 mm. As also shown in
a and 3b also show that magnets 118 are arranged between a yoke 14 or 16 and the contact surface between the two bracelet strands (represented by a dash and dotted line in
According to the invention, the magnets are all polarised normally to the contact surface between the end parts of the bracelet strands. In this regard, it can be seen that the normal to the contact surface is the vertical in
It will also be clear that various alterations and/or improvements evident to those skilled in the art may be made to the embodiments forming the subject of this specification without departing from the scope of the present invention defined by the annexed claims. In particular, those skilled in the art will understand that the second magnetic circuit portions 216 may not include any magnets. Indeed, referring now to
Number | Date | Country | Kind |
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12173916.3 | Jun 2012 | EP | regional |