Patent Grant
9603401
The present disclosure is generally related to clasping and, more particularly, is related to magnetic clasping.
Connecting two ends of an article together has been solved in many ways. These ways include conventional magnetic clasps, toggle clasps, spring ring clasps, barrel clasps, lobster clasps, s-hook clasps, pearl clasps, and box clasps, among others. Some incorporate locks to ensure the security of the clasps. Conventional magnetic clasps rely solely on the magnetic attraction of the magnetic inserts and may become disconnected from each other when subjected to loads exceeding the magnetic attraction of the magnetic inserts. Clasps such as the spring ring and lobster clasps require a manual movement of a lever to open and/or close the clasps. Toggle clasps incorporate a bar and another piece, usually round, that the bar is inserted through to secure the connection. There are heretofore unaddressed needs with previous solutions, including insufficient security, difficulty in securing and/or removing, and unaesthetic addition to the article.
Example embodiments of the present disclosure provide systems of magnetic clasping. Briefly described, in architecture, one example embodiment of the system, among others, can be implemented as follows: a clasp, comprising: at least one magnet; a keyway in a mating surface of the clasp; and a key in the mating surface, the key matched to the keyway.
Embodiments of the present disclosure can also be viewed as providing methods for magnetic clasping. In this regard, one embodiment of such a method, among others, can be broadly summarized by the following steps: providing a pair of clasps, each clasp comprising: at least one magnet; a keyway in a mating surface of the clasp; and a key in the mating surface, the key matched to the keyway; and connecting the mating surface of a first clasp of the pair of clasps with the mating surface of a second clasp of the pair of clasps.
Embodiments of the present disclosure will be described more fully hereinafter with reference to the accompanying drawings in which like numerals represent like elements throughout the several figures, and in which example embodiments are shown. Embodiments of the claims may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. The examples set forth herein are non-limiting examples and are merely examples among other possible examples.
Conventional clasps tend to be difficult for most people to connect and disconnect. Conventional magnetic claps allow ease in connection but are often not secure enough and will come apart. Other clasps lock but are more complex and, so, are difficult to connect and disconnect. In example embodiments of the systems and methods of magnetic clasping disclosed herein, the clasps are self-aligning and can be secured together using one hand. Also, one hand may be used to slide the clasps for release. An example embodiment of the clasps comprise a pair of magnets that secure the clasps together against a forty-five degree angle sliding face. The magnets pull the parts together. While the magnets are pulling the parts together, the key of a first clasp fits into the keyway of a second clasp and the key of the second clasp fits in the keyway of the first clasp. In an example embodiment, the clasps are identical. In an example embodiment, the key and keyway centerlines are perpendicular to a connection hole through the center line of the geometric shape of the clasps, such as a sphere. A connection port, where a linking member connects to the clasp, is perpendicular to the key(s) and keyway(s). The wire may be brought in through the hole and brought around/through a bead or through geometry within the clasp, back out through the hole, and crimped. An example embodiment comprises one hole, but alternative embodiments could include multiple holes. An example embodiment comprises a single key and a keyway in each clasp, but there could be multiple keys and keyways. There could be two keys and two keyways or three keys and three keyways, and still have the same functionality. In an example embodiment, the connection of the wire to the clasp is perpendicular to the center line of the key.
Example embodiments of the systems and methods of magnetic clasping disclosed herein include a a self-aligning interlocking magnetic clasp. When the two halves are placed within close proximity of each other, the magnetic attraction of the magnets within the clasps orient the parts, and the mechanical features of a key, a keyway and a sliding face align. These features hold the two clasps together with the opposed sliding faces coincident and the keys and keyways interlocked, forming a bead shape, for example, with a hole through the middle.
The magnets keep the halves together and the keys and keyways have four faces between the two components that interlock. The perpendicular orientation of the hole to the vertical faces of the key and keyways resist direct forces and tangential or twisting forces applied to the clasp along this axis. This mechanical configuration produces an interlocking, self-aligning magnetic clasp that can resist forces that are multiple times stronger than the magnetic attraction alone.
The disclosed magnetic clasp offer several benefits. The clasp may be plated, painted, et.al to match the other jewelry components that it is combined with, making the clasp virtually invisible. Alternatively, the clasp may be adorned with decoration that would make it the focal point on the jewelry item too. The ability to provide a clasp that resists larger forces in a smaller package permits the clasp to be utilized in numerous applications not typically possible with existing magnetic bead clasps on the market today. The clasp can be installed and removed using one hand. The clasp design may be incorporated into other geometric shapes, e.g. capsule, cylinder, rectangle, etc. Conventional magnetic clasps rely solely on the magnetic attraction of the magnetic inserts and may become disconnected from each other when subjected to loads exceeding the magnetic attraction of the magnetic inserts.
It is an objective of the systems and methods of magnetic clasping disclose herein to overcome the above-mentioned disadvantage of conventional magnetic clasps. An example embodiment of the systems and methods of magnetic clasping disclosed herein is a magnetically attractable self-aligning interlocking jewelry clasp comprising two halves such that when the two halves are placed within close proximity of each other, the magnetic attraction of the magnetic inserts within the clasps orient the components and the mechanical features of key, keyway and sliding face align and secure the two halves together with the opposed sliding faces coincident and the keys and keyways interlocked. The resulting assembled arrangement produces secure clasp with an opening perpendicular to the mechanical features and through the midline of the geometric shape.
In an example embodiment, the magnetic inserts are assembled within the clasp to correctly orient the clasps during connection. The positive and negative axis of the magnetic inserts may be reversed between the pockets of each half. This orientation of the magnetic inserts assists with proper alignment during connection to produce the desired geometric shape. In addition, the magnetic repulsion created from this assembled geometry assists with the removal of the jewelry clasp. As a result of the interlocking attachment provided by the mechanical means of the clasp, the clasp may be slid apart along the plane parallel to the key and keyway and against the sliding face to remove the jewelry item. As the magnetic insert approaches the opposing magnetic insert in the adjacent clasp, the opposing magnetic forces repulse the adjacent clasp and disengage the clasps from one another. This magnetic repulsion minimizes the distance required to slide the halves during disassembly.
In an example embodiment, clasps 300A and 300B each comprise two magnets, a first magnet and a second magnet, both flush with mating surfaces 340, 345 and both at 45 degree angles with the midpoint planes 370 and 380. The first magnet of clasp 300A has a first polarity (such as North) at mating surface 340 and the second magnet has a second polarity, opposite from the first polarity (such as South) at mating surface 340. The first magnet of clasp 300B has a first polarity (such as North) at mating surface 345 and the second magnet has a second polarity, opposite from the first polarity (such as South) at mating surface 345. When clasp 300A is mated with clasp 300B the first magnet (with the first polarity) of clasp 300A mates with the second magnet (with the second, opposite polarity) of clasp 300B and the second magnet of clasp 300A (with the second, opposite polarity) mates with the first magnet of clasp 300B (with the first polarity). The magnetic forces of magnets 350 and 355 attract clasps 300A and 300B together, and the mating of keys 320 and 325 into keyways 335 and 330, respectively, secure the clasps from pulling apart. To pull clasps 300A and 300B apart, the clasps are moved laterally along the key/keyway until the magnets are no longer attracting and they clasps are easily pulled apart.
In an example embodiment, connection port 590 extends through clasp 500, from outer surface 510 to mating surface 540 and between the first magnet and the second magnet. Connection port 590 may be configured to be ninety degrees from parallel midpoint planes 570 and 580. In an example embodiment, connection port 590 is graduated from smaller near outer surface 510 to larger at mating surface 540. In an example embodiment of connecting the clasp to the end of a necklace, as a non-limiting example, the end of the necklace string may be passed through the outer surface end of connection port 590 and out of the mating surface end of connection port 590, around a looper means (for example through a bead or around a grooved loop) and back through connection port 590 from mating surface 540 to outer surface 510, where it may be crimped using various means. The looper means may be configured to be small enough to fit in connection port 590 on the mating surface end, but not fit through connection port 590 on the outer surface end.
In an alternative embodiment, instead of using connection port 590, the connection of the necklace end, for example, may be connected directly to outer surface 510 (for example, by soldering), or tied to a connector which is, for example, soldered directly to outer surface 510. Although the connection may be made to clasp 500 at any point on outer surface 510, it is preferable that the tension from the connection be at ninety degrees from parallel midpoint planes 570 and 580. Alternatively, the necklace may be manufactured with outer surface 510.
In an example embodiment, connection port 670 extends through clasp 600, from the outer surface to mating surface 640 and between magnet 650 and magnet 660. Connection port 670 may be configured to be ninety degrees from the parallel midpoint planes. In an example embodiment, connection port 670 is graduated from smaller near the outer surface of clasp 600 to larger at mating surface 640. In an example embodiment of connecting the clasp to the end of a necklace, as a non-limiting example, the end of the necklace string may be passed through the outer surface end of connection port 670 and out of the mating surface end of connection port 640, around a looper means (for example through a bead or around a grooved loop) and back through connection port 670 from mating surface 640 to the outer surface of clasp 600, where it may be crimped using various means. The looper means may be configured to be small enough to fit in connection port 670 on the mating surface end, but not fit through connection port 670 on the outer surface end. In an alternative embodiment, connection port 670 may comprise parallel holes to create a looping means within clasp 600.
In an example embodiment, connection port 790 extends through clasp 700, from the outer surface to mating surface 740 and between first magnet 750 and second magnet 760. Connection port 790 may be configured to be ninety degrees from the parallel midpoint planes. In an example embodiment, connection port 790 is graduated from smaller near the outer surface of clasp 700 to larger at mating surface 740. In an example embodiment of connecting clasp 700 to the end of a necklace, as a non-limiting example, end 780 of necklace string 797 may be passed through the outer surface end of connection port 790 and out of the mating surface end of connection port 790, around looper means 795 (for example through a bead or around a grooved loop) and back through connection port 790 from mating surface 740 to the outer surface of clasp 700, where it may be crimped using crimping means 785. Looper means 795 may be configured to be small enough to fit in connection port 790 on the mating surface end, but not fit through connection port 790 on the outer surface end.
Although example embodiments of the clasps have been shown through jewelry implementations, the clasps have many other uses such as a detachable lure for a fishing line, connecting ropes between posts, backpacks, et cetera. Although shown as a sphere, a pair of clasps may take any shape, such as a cube, a pyramid, capsule, cylinder, or any other shape or figure.
Although the present invention has been described in detail, it should be understood that various changes, substitutions and alterations can be made thereto without departing from the spirit and scope of the invention as defined by the appended claims.
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