Patent Grant
7013674
The present invention relates to jewelry components that are magnetically attractable to each other so a plurality of such components can be joined or combined into rings, bracelets, chains, chokers, necklaces, watchbands or the like, with the magnetic force holding the components together. Also, components can be connected in any one of a number of positional relationships so that the final jewelry article is self-sizing to the wearer.
When a person wishes to purchase an article of jewelry to be worn, care must be taken to assure that the size of the piece is correct. When purchasing an item such as a bracelet or necklace, the size is selectable from one of a plurality of standard lengths at the desire of the purchaser. Other items, such as watchbands, are provided with removable links so that the size can be selected to conform to the size of the person's wrist. For other items, such as a ring, the jeweler will usually measure the size of the person's finger so that the ring can easily slide along the person's finger into place. It is often difficult to properly size the ring so that it can be snugly maintained in place as it must also be sufficiently large to pass over the person's knuckles, especially for people that have arthritic joints. This means that the ring must be sized larger to accomplish this and then will be too loose when in the proper position. Also, the person's finger can change in size over the years, and a ring that is correctly sized at one time can end up being incorrectly sized in the future.
The accommodation of different sizes creates difficulties for the jewelry manufacturer and seller, in that different sizes must be made available, or specialized orders must be custom made to the person's actual or desired dimensions. It would be desirable to avoid having to carry large inventories of different sized jewelry articles, as well as to avoid having to make custom sized pieces for each customer. These problems are now solved by the present invention.
The present invention relates to a jewelry-forming component comprising a body member having a first magnetized portion and at least one female element associated therewith for magnetically attracting and receiving a male element of another jewelry-forming component. The first magnetized portion of the body member provides a minimum magnetic strength that is sufficient to retain the male element within the female element and a maximum magnetic strength that can be overcome by a person's hand strength to separate or push apart the male and female elements. The body member also includes a further element that is magnetically responsive for magnetically coupling with another jewelry-forming component, such that a plurality of such components can be magnetically coupled to form an article of jewelry.
The female element may be defined by a cavity having a configuration and depth sufficient to receive the male element at different positional relationships therein, and this allows relative movement between the male and female elements. Advantageously, the body member has an arcuate shape and the female element is located at an end of the arcuate shape. These male and female elements can be matably engaged in the different positions to assist in providing a preferred self-sizing feature to the article.
In one embodiment, the body member has an arcuate shape and first and second female elements are located at each end thereof, with each female element defining a cavity having a depth sufficient to receive a male element at different positional relationships therein. Each female element would be magnetized to attract and hold oppositely polarized male elements therein. The male element can be part of another all male component or a male/female component as described herein.
In another embodiment, the further element is a male element that extends away from the female element and is located on the opposite end of the arcuate shape, wherein the male element has a forward end that is magnetically attracted to the first magnetizable portion of the body member. Thus, a male element of one component is inserted into the female element of another component and the male element of that component is inserted into the female element of another component. This continues until all the components are interconnected and held in magnetic association to form the article.
In yet another embodiment, the further element is another female element that is located on the opposite side of the component. The dual female element jewelry-forming component is magnetized to attract and hold oppositely polarized male elements therein. The male elements may be provided by arcuate rods having ends that are magnetized and that are configured to be received in the ends of the tubular structure. The body of the female component may be magnetized or it may include therein a magnetized pellet or disk member. The male elements are magnetized to an opposite polarity so that magnetic connections can be achieved between the male and female elements. When the female elements are provided as part of a tubular body member, the first magnetized pellet or disk member can be placed within each end of the tubular structure to define the female element cavities.
A jewelry article according to the invention can be provided by combining various combinations of the previously mentioned components or with other magnetized components. The article can be provided in the form of a ring, bracelet, chain, choker, necklace, watchband or other item with a closed or closable continuous configuration and is made from a plurality of jewelry-forming components as described herein. Depending upon the size of the components and the size of the article, any number of these components can be used. For most common sizes, between two and two hundred jewelry-forming components can be connected depending upon the selected size of the component and the desired size of the article. A most preferred article is in the form of a ring, wherein at least two to thirty components are connected end to end to form the article.
A specific embodiment of the invention relates to a jewelry article comprising at least two jewelry-forming components that have a first end and a second end, wherein the first ends of the components are magnetically coupled to the second ends of other components to form an article having a closable or closed, continuous configuration. At least one end of each component is configured to receive the other end of another component in a plurality of positions so that the article is self-sizing to the wearer. As noted above, the jewelry article is preferably in the form of a ring, bracelet, chain, choker, necklace or watchband.
The invention is more fully understood by reviewing the following detailed description in conjunction with the appended drawing figures, wherein:
Any cross sectional configuration of the male and female elements is possible. Although shown as round in the preferred embodiments of these components, other configurations such as polygonal, elliptical or combinations thereof. While the male and female components are preferably of the same configuration, this is not necessary and any matable configurations can be used. Also, the shape of the outer surface of these components is unlimited and can be of any desired shape with or without additional ornamentation, undulations, or other surface characteristics.
It is this movement in combination with the magnetic attraction of the elements that allows the ring to be self-sizing. The movement of the parts is illustrated in
In another arrangement, illustrated schematically in cross-section
In the most compact state of the ring or jewelry piece, each male element is inserted as far as possible into the female element. A cavity of finite depth can be used so that the forward end of the male element stops by abutting the innermost end of the female element. Alternatively, when a tube or tubular cavity is used as the female element, the rearward portion of the male element can be provided with a shoulder or other protrusion which will act as a stop. These define the smallest size of the piece. Of course, each component can be separated so that a much larger size is provided.
The ring of
“Self-sizing to the wearer” means that the article of jewelry includes jewelry-forming components that in one configuration has magnetically attracted elements that provide a minimum circumference, perimeter or length to the article, but that the elements may be moved relative to each other so that the article can attain a maximum circumference, perimeter or length which facilitates placement of the article around the finger, wrist, ankle, arm, leg, neck or waist of the wearer. Generally, the magnetically attracted components can be separated or moved further apart by the hand strength of the wearer so that a larger size of the article is achieved; and that after placement on the wearer, the elements are magnetically attracted to the extent that a smaller or comfortably snug fit of the article on the wearer is achieved without uncomfortably compressing or squeezing the body part of the wearer.
While the drawing figures utilize rings as preferred examples of jewelry articles that can be made from the magnetic jewelry components of the invention, the skilled artisan would of course recognize that other items, such as bracelets, ankle or belly chains, necklaces or watchbands can be made in the same manner. In those pieces, however, the parts can be designed with a different curvature and a larger number of components would be magnetically joined together to make the piece. As to curvature and overall configuration of the components, anything from a straight to any appropriately curved configuration would be acceptable, and the user could select different combinations depending upon the desired final visual appearance of the article.
As above, different stones, settings or other decorative or ornamental elements can be carried by one or more or even by all of the components. For these types of articles, a clasp or other closure element is not necessarily required as the parts are retained in connection due to magnetic force. Of course, there is no reason why a conventional clasp or other end joining member cannot be used, if desired, for a particular effect.
This connection feature is obtained by providing the mating portions of the components with sufficient magnetic strength so that the elements try to move as closely together as possible. This is conveniently achieved by providing a magnetic strength of between 200 and 4500 Gauss depending upon distances between the parts, types, shapes and sizes of magnets, etc. As the skilled artisan would know, this magnetic strength should be sufficiently low that the elements can be easily separated either by simply sliding the article over the finger, foot, hand, head, legs or torso of the wearer, or by using hand strength to pull apart or expand the article. Depending upon the specific designs utilized, the article can be separated into the jewelry-forming components or the components can be moved to different relative positions, thus enabling the article to temporarily assume an expanded or larger size configuration to facilitate placement on the wearer.
As noted above, the magnetized portion of the body member has a sufficiently high magnetic strength to retain the male member within the female member to hold the jewelry article together, but this magnetic strength is not greater than that provided by the strength of an average person's hands. Thus, the person or wearer of the article has enough strength to retract or pull apart the male member at least partially from within the female member. This enables the size of the article of jewelry to be adjustable to accommodate placement on the wearer. In some designs, if desired or necessary, the components can be disassembled to allow cleaning or rearrangement. Different components can reassembled in a different arrangement, if desired, or can be interchanged with other components of similar size to provide a different appearance to the piece, e.g., by providing different colors, stones or other items to match the clothing or the wearer or to simply provide a different visual effect to the piece.
In a preferred embodiment, the inner surface of the female element has a relatively uniform circumference so that the male element can easily move into or out of the female element. This enables the components to be separated or taken apart for ease of removal or for cleaning. This construction also facilitates reconnection of the components in different combination or with different components to alter or modify the overall appearance of the ring. Although two components are illustrated in
In another preferred embodiment, a four-part ring 100 can be made in a slightly different way, as illustrated in
Female component 80 is an arcuate tube the entire body of which is magnetized to one polarity while male component 95 is a solid arcuate rod that is magnetized with an opposite polarity to that of the female component 80. Male component 90 illustrates another feature of the invention, namely the use of a hinge 70 that allows the ends 90A, 90B of the male component to move relative to each other as those ends are slidingly coupled with the female elements 80, 85. Of course, male elements 90A, 90B would be magnetized with a polarity that is opposite to that of the female components 80, 85 so that those parts can be magnetically coupled.
Female component 85 illustrates an alternative embodiment, where a magnetized pellet or disk 75 having the opposite polarity to that of the polarized male components 90B, 95. This pellet or disk 75 can be inserted in the interior of the tubular female element 85 and spaced from the ends so that it can provide a magnetic force that attracts the opposite magnetic force of the male elements 90B, 95. This pellet or disk 75 can vary over a wide range of sizes and shapes, its only requirement being that it have a sufficient magnetic strength to attract the forward end of the male element in the manner described herein. Conveniently a circular disk, reminiscent of a miniature coin, as shown, is the easy to manufacture and assemble, and is preferred. This disk 75 can be adhered or otherwise affixed in place near the center of the cavity of the tubular female component 85 so that it cannot be dislodged or removed. The disk can be fixed in place using an adhesive, a solder, or a mechanical construction, such as a press fit, retaining screw or pin etc. In addition, the arcuate tube female component 85 can retain more than one disk therein, with each disk placed adjacent the final position of the male components therein. When a hollow tube is used, the disks can form the ends of the female cavities and act as a stop to the insertion of the male components. In the ring of
The outer surface of the female element is generally illustrated as being uniform, but it also can be stepped or tapered as selected by the designer to achieve the desired visual effect. The taper presents a smooth transition between the male and female elements. The same is true for the design of the male element, keeping in mind that it must be shaped and size fit within the female element. Also, tapering of the male element can be used to provide a stop which prevents too great of a contraction of the size of the ring. Other stop members can be provided, such as pins, collars, stepped surfaces or the like. This stop member can also be controlled by the length of the male member and its abutting to the inside end of the female member. The female and male portions can be configured in any manner as described above so long as they allow the male elements to move easily into and out of the female elements. Also, as described above, the design of the female cavity and male end can be used to control the minimum size of the jewelry article.
Typical sizes for the jewelry-forming components of the invention can vary over a wide range. Generally, arcuate shaped components are used, but the designer has an unlimited selection of desirable sizes, shapes, colors, etc., depending upon the visual effects to be achieved, of course limited only by sizes that can be worn by the wearer without discomfort or injury.
Any magnetizable material can be used in the present invention, but for fine jewelry the invention preferably utilizes magnetic precious metal alloys that have magnetic properties and high hardness. These magnetic precious metal alloys are ideally suited for making various forms of fine jewelry that provide new and unusual visual and functional properties. The alloy's magnetic properties enable the components to either be attracted to or repelled by other components of different or like polarities. This, in turn, enables the jewelry designer to create a variety of precious metal pieces with magnetically connected components. A wide range of new precious metal jewelry components can now be made with heretofore unknown connections due to the magnetic properties of the alloys that are used therein.
The preferred alloys are platinum based and contain at least about 70% platinum by weight. While amounts as high as 95% by weight are suitable, the most preferred amount is between 75 and 80% by weight as these amounts enable the strongest magnetic properties to be achieved. In order to impart magnetic properties to these alloys, cobalt is added and the alloy is heat-treated. The amount of cobalt can range from about 5 to 30% by weight, and is complementary to the weight of the platinum. As between these two components, a weight ratio of 70:30 to 95:5 Pt:Co is preferable. An example of this material is known as POLARIUM® and is available from the inventor. This alloy is preferred for fine jewelry because it has greater magnetic power than known magnetic gold alloys.
The components of the invention can be used for many purposes. For example, a conventional necklace can be provided with a plurality of components that have oppositely polarized male (or female) elements extending away from the wearer. Then a plurality of ornamentations, such as gem or stone settings or metal shapes, e.g., cubes, polygons, figures, letters or numbers, etc., can be provided with a female (or male) element of opposite magnetic polarity to that of the male elements, This allows the user to connect the ornamentations onto the necklace in a desired manner by magnetically coupling the male and female elements. This arrangement allows the user to custom design the necklace for the occasion by adding the desired stones and other ornamentations, Moreover, since the couplings are not permanent, the necklace can be rearranged or redesigned as desired for future uses.
By including an appropriate post or clasp arrangement on one of the jewelry-forming component of the invention, the skilled artisan is able to create a wide range of earring designs from such components. In addition, one of ordinary skill in the art would recognize that the components of the invention can be used in combination with additional functional parts such as hinges, rivets, ball and socket joints, and other engineered items that allow for motion between the components. When a ball and socket type joint is used, the ball and socket can be magnetized with different polarities so that the can be maintained together in magnetic association. The final jewelry articles that can be made vary greatly, thus demonstrating the versatility of the jewelry-forming components of the invention.
| Number | Name | Date | Kind |
|---|---|---|---|
| 486256 | Leehey et al. | Nov 1892 | A |
| 2623256 | Feibelman | Dec 1952 | A |
| 3263444 | Di Croce | Aug 1966 | A |
| 3423956 | Manne | Jan 1969 | A |
| 3589341 | Krebs | Jun 1971 | A |
| 4221615 | Shine | Sep 1980 | A |
| 4853048 | Shimizu et al. | Aug 1989 | A |
| 4901405 | Grover et al. | Feb 1990 | A |
| 4905335 | Tervola | Mar 1990 | A |
| 4941236 | Sherman et al. | Jul 1990 | A |
| 4983230 | Overfelt et al. | Jan 1991 | A |
| 5008984 | Levy | Apr 1991 | A |
| 5050276 | Pemberton | Sep 1991 | A |
| 5097682 | Nakamura | Mar 1992 | A |
| 5099659 | Carranza et al. | Mar 1992 | A |
| 5197168 | Levy | Mar 1993 | A |
| 5307582 | Quintel | May 1994 | A |
| 5311647 | Levy | May 1994 | A |
| 5317789 | Levy | Jun 1994 | A |
| 5323516 | Hartmann | Jun 1994 | A |
| 5349725 | Levy | Sep 1994 | A |
| 5353608 | Berkowitz | Oct 1994 | A |
| 5367891 | Furuyama | Nov 1994 | A |
| 5392497 | Definer | Feb 1995 | A |
| 5412956 | Levy | May 1995 | A |
| 5432986 | Sexton | Jul 1995 | A |
| 5586374 | Nishida | Dec 1996 | A |
| 5664298 | Nessar-Ivanovic | Sep 1997 | A |
| 5675874 | Chen | Oct 1997 | A |
| 5722260 | Mangano | Mar 1998 | A |
| 5806346 | Schlinger et al. | Sep 1998 | A |
| 5913707 | Roman et al. | Jun 1999 | A |
| 5920966 | Chen | Jul 1999 | A |
| 5989178 | Chiu | Nov 1999 | A |
| 6116053 | Siebenberg | Sep 2000 | A |
| 6116982 | Roman et al. | Sep 2000 | A |
| 6282760 | Mars | Sep 2001 | B1 |
| 20020069670 | Rosenberg | Jun 2002 | A1 |
| 20030177787 | Kuo | Sep 2003 | A1 |
| Number | Date | Country |
|---|---|---|
| 271423 | Jun 1988 | EP |
| 2055552 | Mar 1981 | GB |
| 2002125729 | May 2002 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20040200235 A1 | Oct 2004 | US |
