Jewelry module

Abstract

Disclosed is a jewelry module in which each core module is formed by connecting each other in jewelry produced by processing precious metals. The jewelry module has a rotation bed having an axis of rotation formed so as to be centered on the joining axis of each core module. Additionally, an angle of rotation with a reduced distance away from the rotational movement of each core module by the presence of said axis of rotation is provided, and a connection bracket is centered on the axis of rotation, which grasps the rotation bed and enables one core module to be connected with the other core module.

Claims

1. A jewelry module comprising: a plurality of core modules each being of a monolithic structure, each of said plurality of core modules being connected to at least one other core module of said plurality of core modules, each of said plurality of core modules being formed of a processed precious metal; a rotation bed positioned on each of said plurality of core modules, said rotation bed having a central rotation axis along a joining axis, said rotation bed allowing symmetrical movement while preventing lateral movement of each of said plurality of core modules, wherein an angle of rotation is formed by a displacement between adjacent core modules of said plurality of core modules during rotational movement around the central rotation axis, a semicircular pin space being formed within each core module of said plurality of core modules, the semicircular pin space dimensioned to receive an outer semicircular portion of said rotation bed; and a connection bracket positioned about the central rotation axis, said connection bracket interlocking with said rotation bed via a joining space, wherein the rotation bed prevents deviations from the central rotation axis, the interlocking of said connection bracket eliminating gaps between said plurality of core modules.

2. The jewelry module of claim 1, wherein the central rotation axis extends symmetrically along an entire length of the jewelry module, the entire length being divided into a first half length and a second half length, wherein the central rotation axis is positioned centrally along the joining axis within each core module of said plurality of core modules.

3. The jewelry module of claim 1, wherein said rotation bed is a monolithic structure and is adapted to balance movement of said plurality of core modules along a direction of rotation and to prevent lateral movement in response to external forces.

4. The jewelry module of claim 3, wherein each core module of said plurality of core modules has mounting gap therein so as to allow said connection bracket to move in a circular path along the direction of rotation.

5. The jewelry module of claim 1, wherein each core module of said plurality of core modules has a joining space that accommodates a bending and securing of said connection bracket.

6. The jewelry module of claim 1, wherein each core module of said plurality of core modules has a fixer formed integrally therewith, the fixer adapted to secure a precious stone mounted on the jewelry module.

7. The jewelry module of claim 1, wherein said connection bracket has a bending end that engages said joining space by wrapping around a surface of the rotation bed, the bending end being bent so as to secure the rotation movement of said plurality of core modules.

Description

DESCRIPTION OF THE FIGURES

(1) FIG. 1 is the perspective view of the general assembly and disassembly of the jewelry module, which is the subject of the invention.

(2) FIG. 2 is the three-dimensional individual perspective view of the jewelry module, which is the subject of the invention.

(3) FIG. 3 is the two-dimensional view of the jewelry module, which is the subject of the invention, from the A direction.

(4) FIG. 4 is a two-dimensional representative view of the core modules that make up the jewelry module, showing the axis of rotation, with the bending end open

(5) FIG. 4.1 is another representative view showing the axis of rotation of the core modules that make up the jewelry module with the bending end bent

(6) FIG. 4.2 is a representative two-dimensional view showing the angle of rotation.

(7) FIG. 4.3 is a cross-sectional representative two-dimensional view showing the angle of rotation.

(8) FIG. 4.4 is a representative view of the core modules that make up the jewelry module, with the bending end open and closed.

PART NUMBERS

(9) 10Jewelry module 20Core module 21Rotation bed 22Connection bracket 22.1 Bending end 23Pin space 24Joining space 25Fixer 26Mounting gap 30Precious stone AViewing direction BCenter of rotation CJoining axis DAngle of rotation x, x1Direction of rotation tFull length t1Half length t2Other half length

DETAILED DESCRIPTION OF THE INVENTION

(10) FIG. 1 illustrates a jewelry module (10) in which each core module (20) is connected to each other in jewelry produced by processing precious metals.

(11) FIGS. 4, 4.1 and 4.2 shows the rotation bearing (21) with a rotation axis (B) formed to be centered at the junction axis (C) of each core module (20) and with the presence of the said rotation axis (B), the rotation angle (D) of each core module (20) is obtained with a reduced distance of departure is obtained by the rotational movement. Thus, the rotation angle (D) between both core modules (20) is reduced. Due to the fact that this rotation angle (D) is much higher than the acceptable dimensions in the present technique, an appearance is formed in the axial rotation of the core modules (20) that disturbs the aesthetic appearance.

(12) The semicircular pin space (23) in which the semi-circular part of the said rotation bearing (21) will be positioned, and the rotation bearing (21) centered on the rotation axis (B) that enables a core module (20) to be connected with the other core module (20) by grasping the said rotation bearing (21) includes the connecting bracket (22). Likewise, it comprises a rotation axis (B) with half length (t1) and other half length (t2) equal to each other, configured to be exactly in the middle of each core module (20) by placing two core modules (20) side by side. (see FIG. 4.1).

(13) In case an external force is applied, jewelry wobble (off-axis movements) is prevented by means of the rotation bed (21) by ensuring the balanced movement of the jewelry module (10) in the x-x1 direction of rotation in a monolithic structure with the said core module (20). However, the said core module (20) contains a pin space (23), which is formed in the inner part of the core module (20) in such a way that the adjacent jewelry modules (10), which are formed in such dimensions that the rotation bed (21) can be placed, are rigidly joined in such a way as to ensure their movement in the x-x1 direction of rotation. In addition, the jewelry module (10) includes a connection bracket (22), which grasps the said rotation bed (21) and enables one jewelry module (10) to be joined with another jewelry module (10) in such a way that they cannot be separated from each other, and a joining space (24), which enables the connection bracket (22) to be placed and welded into it by bending during the joining of the jewelry modules (10). In addition, it has a center of rotation (B), which is positioned as a common balance point of adjacent jewelry modules (10) side by side in the combination of jewelry modules (10) and enables the movement of jewelry modules (10) in x-x1 directions without damaging each other.

(14) On the other hand, the jewelry module (10) is formed in a monolithic structure with the core module (20) in such a way that the aforementioned connection bracket (22) can pass through it and the mounting gap (26) is formed to allow the jewelry module (10) to move in the x-x1 directions. This core module (20) is formed in a monolithic structure with the module (10), and includes a fixer (25) for fixing the precious stones (30) mounted on the jewelry module (10).

(15) The inventive jewelry module (10) includes a core module (20), and comprises a rotation bed (21), a connection bracket (22), a pin space (23). The connection bracket (22) of one said jewelry module (10) is passed through the mounting gap (26) so as to engage the rotation bed (21) of another jewelry module (10). The connection bracket (22) is bent by means of a force, inserted into the joining space (24) of its own jewelry module (10) and welded. Simultaneously with this process, the rotation bed (21) of the first jewelry module (10) is inserted into the pin space (23) of the other jewelry module (10). Moreover, this connection is made especially thanks to the center of rotation (B) so that both jewelry modules (10) are balanced and can rotate freely in the x-x1 directions of rotation. After the bending end (22.1) is inserted into the rotation bed (21), it is bent into a rotational movement.

(16) Thus, when a force is applied to a piece of jewelry made of the aforementioned jewelry modules (10) to twist the jewelry, there is no twisting or wobbling of the jewelry due to the combination of the rotation bed (21) and the pin space (23) at the center of rotation (B).