JEWELRY MODULE IN WHICH A RIGID STRUCTURE WITH FEW PARTS IS OBTAINED

Abstract

A lock assembly of a jewelry module used for joining the jewelry parts to each other in jewelry having more than one part, wherein the lock assembly provides for a compact structure and hides the lock components and to obtain a rigid structure. The lock assembly includes a module body which allows the entry of a lock striker in the horizontal axis (X), which allows the positioning of a movable lock in the vertical axis, a positioning area in which the movable lock is concealed, a movable lock which is fixed in the positioning area by a bearing cavity and positioned for rotary movement, the movable lock having a rotational axis (P) which provides a rotational movement restricted by contact of the movable lock with the pressure surface, and a nail which disengages from the nail slots by the rotational axis (P) and by contact with a pressure surface.

Claims

1. A lock assembly of a jewelry module used for joining jewelry parts to each other in earrings and bracelets type jewelry joined by methods known as chain or waterway, the lock assembly comprising: a module body arranged in a side-by-side arrangement without the need to form an independent lock body, which allows the entry of a lock striker on the horizontal axis (X) and at the same time allows the positioning of a movable lock on the vertical axis (Z), in order to obtain a compact structure and to hide the lock components and to obtain a rigid structure, a positioning area in which said movable lock is concealed, a lock slot formed along the x-axis of module bodies arranged side by side, wherein the movable lock is fixed in a positioning area by means of a bearing cavity and positioned for rotary movement, an axis of rotation (P), which provides the rotational movement restricted by the contact of said movable lock with a pressure surface, and a nail which is separated from nail slots by means of said axis of rotation (P) and in contact with the pressure surface, wherein the module body comprises another bearing cavity, which is centred by the bearing cavity and provides limited rotational movement for the movable lock.

2. The jewelry module according to claim 1, comprising a bearing pin in such a way that it fixes the movable lock in a pivoting movement by means of said bearing cavity.

3. The jewelry module according to claim 1, comprising a spring which enables said nail to be inserted into the nail slots and the nail to exert a forced force on the nail slots in a continuous vertical axis (Z) direction.

4. The jewelry module according to claim 1, comprising at least one spring cavity in which said spring is positioned.

5. The jewelry module according to claim 1, wherein the movable lock has a spine elevation for obtaining a resistant structure, in the form of a channel extending along said spine elevation and having a spring cavity providing high resistance for the spring.

6. The jewelry module according to claim 1, wherein said movable lock comprises pressure edges formed on the edges of the pressure surface.

7. The jewelry module according to claim 1, comprising a lock bearing in which double-acting locking is provided as a result of turning said movable tongue to 90 degrees and bearing it to the axis of rotation (P) from both lateral regions.

8. The jewelry module according to claim 7, comprising at least two movable tongues positioned on said lock bearing by means of at least two rotation axes (P).

9. The jewelry module according to claim 1, comprising an angular structure lock slot for restricting the movement of each module body in the direction of the axes of rotation, and a cylindrical rotation projection in the form of a half-moon on the rear wall starting from the lower long side of said lock slot.

10. The jewelry module according to claim 1, comprising a slider unit having a slider arm which is moved by means of at least one hinge movement unit.

11. The jewelry module according to claim 10, comprising a fixed knob which is fixed by means of a movable knob to the fixing range of said slider arm.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0023] FIG. 1 is a general view of a part of the inventive jewelry module.

[0024] FIG. 1A is a two-dimensional disassembly view of the inventive jewelry module and lock assembly from the top.

[0025] FIG. 2; is a three-dimensional general disassembly view of the inventive jewelry module and lock assembly.

[0026] FIG. 3 is a two-dimensional disassembly view of the inventive lock assembly from the side.

[0027] FIG. 4 is a two-dimensional side view of the inventive lock assembly when the lock is active.

[0028] FIG. 5; is the view of the lock deactivated as a result of applying pressure to the inventive lock assembly.

[0029] FIG. 6 is a close-up disassembly view of the alternative structure, preferably including a double action lock, in which the rotation protrusion is shown in the inventive jewelry module.

[0030] FIG. 6A is a two-dimensional top view of the alternative structure comprising a double-action lock.

[0031] FIG. 7 is a perspective view of the inventive lock assembly applied to the earring.

[0032] FIG. 8 is a perspective view of the inventive lock assembly applied to a wrist clamp.

[0033] FIG. 8A is a close-up sectional view of the lock assembly applied to the cuff.

PART NUMBERS

[0034] 1Earring [0035] 2Bracelet [0036] 10Jewelry module [0037] 11Module body [0038] 12Lock slot [0039] 12.1Angular structure [0040] 12.2Lower long side [0041] 12.3Rotation projection [0042] 12.4Contact end [0043] 12.5 Rear wall [0044] 13Bearing cavity [0045] 14Positioning area [0046] 15Radius edge [0047] 16Lock bearing [0048] 20Lock striker [0049] 21Lock body [0050] 22Nail slots [0051] 23Discharged area [0052] 30Movable lock [0053] 31Lock body [0054] 32Nail [0055] 33Spring cavity [0056] 34Bearing cavity [0057] 35Pressure edges [0058] 36Spring [0059] 37Bearing pin [0060] 38Pressure surface [0061] 39Spine elevation [0062] 40Slider unit [0063] 41Hinge movement unit [0064] 42Slider arm [0065] 43Fixing range [0066] 44Fixed knob [0067] 45Movable knob [0068] Paxis of rotation [0069] XHorizontal axis [0070] ZVertical axis [0071] ALock assembly [0072] Yrotation axis

DETAILED DESCRIPTION OF THE INVENTION

[0073] In FIGS. 1, 1A and 2, a lock assembly (A) of jewelry module (10) used for joining the jewelry parts to each other in earrings (1) and bracelets (2) type jewelry joined by methods known as chain or waterway is illustrated.

[0074] In order to obtain a compact structure and to hide the lock components and to obtain a rigid structure, the invention includes a module body (11) which allows the entry of the lock striker (20) on the horizontal axis (X) and the positioning of the movable lock (30) on the vertical axis (Z). It has a positioning area (14) in which said movable lock (30) is concealed, and a lock slot (12) in which said lock striker (20) is inserted in a linear movement. As can be seen in FIG. 2, the module body (11) has a main shelter feature that allows the assembly of lock components from two different areas. Module body (11) has a rootstock structure. It provides a concealable structure with the lock striker (20) and movable lock (30) and helps to create aesthetics in jewelry.

[0075] In the said positioning area (14), the movable lock (30), which is fixed by means of the bearing cavity (13) and positioned to rotate, and the axis of rotation (P), which provides the rotational movement limited by the contact of the said movable lock (30) with the pressure surface (38). It comprises a nail (32) which is disengaged from the nail slots (22) by means of said axis of rotation (P) and by contact with the pressure surface (38). The lock is activated and deactivated by means of a movable lock (30). As a result of applying pressure to the pressure surface (38) by finger contact (see FIG. 5), the nail (32) is disengaged from the slots and thus the lock is deactivated and the locking is deactivated by pulling the lock striker (20) backwards in the opposite direction on the horizontal axis (X). The opposite of this process, i.e. the locking is activated in the opposite direction, i.e. the locking is activated as a result of the spring (36) being pressed by the continuous force of the spring (36) in the area where the nails (32) are positioned, as the lock striker (20) is driven forwards on the horizontal axis (X), the nail (32) engages in the nail slots (22).

[0076] Furthermore, the nail slots (22) may be at least two or more in number depending on the shape and structure of the stone or the slot. The nail slots (22) can be increased or decreased. The springs (36) can be made of steel or titanium material, or they can be made of gold hardened material or material of 8, 10 or 22 carat purity.

[0077] A bearing pin (37) is used to fix the movable lock (30) in a rotary movement by means of the bearing cavity (13) formed on the module body (11). The bearing pin (37) secures the module body (11) and the movable lock (30) by means of the bearing cavity (13). However, a bearing cavity (34) is formed which is centred with the bearing cavity (13) of the module body (11) and provides limited rotational movement for the movable lock (30).

[0078] A spring (36) and at least one spring cavity (33) in which the said nail (32) is positioned, which enables the said nail (32) to be inserted into the nail slots (22) and the nail (32) to exert a forced force on the nail slots (22) in the direction of the continuous vertical axis (Z), are formed on the movable lock (30).

[0079] A spine elevation (39) is formed on said movable lock (30) in order to obtain a resistant structure. A spring cavity (33) in the form of a channel extending along this spine elevation (39) and providing high resistance for the spring (36) is formed. On the other hand; pressure edges (35) are formed on the edges of the pressure surface (38) of the movable lock (30).

[0080] FIG. 1 shows a slider unit (40) having a slider arm (42) actuated by means of at least one hinge movement unit (41), and said slider arm (42) comprises a fixed knob (44) fixed in the fixing range (43) by means of a movable knob (45).

[0081] In FIG. 2, the lock slot (12) is formed along the x-axis in the module bodies (11) arranged side by side in rows without the need to form an independent lock body. Each module body (11) arranged in a row contains a lock slot (12) along its length. It allows the entry of the lock striker (20) in the x-axis, while at the same time allowing the positioning of the movable lock (30) from the bottom, i.e. in the Z-axis. Thus, lock bodies and lock cavities are formed directly by means of module bodies (11) without the need to form a lock body as in FIG. 6.

[0082] In FIG. 6, the modules (10) arranged in rows by means of the lock slot (12) in which the contact end (12.4) is positioned, and the lock slot (12.1) in an angular structure (12.1) whose movement in the direction of the axes of rotation of these core modules (10) is restricted, start from the lower long side (12.2) of the said lock slot (12) and include a rotation projection (12.3) in a cylindrical structure in the form of a half-moon on the rear wall (12.5). By means of the half-moon shaped cylindrical rotation projection (12.3), the desired movement of the modules in the rotation axis (Y) is provided. This structural feature has an effect on the stabilization of the product. Thus, the jewelry worn on the neck area of the person, especially the modules in which the precious stones are placed, exhibit a stable posture parallel to the chest. As a result of the stable posture of the modules parallel to the chest, posture disorders are prevented.

[0083] In FIGS. 6 and 6A, the two-dimensional view of the structure including the double movable lock (30) with alternative structure is illustrated from the top. It is possible to provide double-acting locking as a result of turning the movable lock (30) to 90 degrees and bearing it to the axis of rotation (P) from both lateral regions. The lock assembly shown in FIG. 6 is the same as the lock assembly shown in FIG. 2. However, in this alternative structure, it is possible to provide double-acting locking by means of movable locks (30) positioned on both sides. This double action is provided by means of a lock bearing (16). At least two axes of rotation (P) and at least two movable locks (30) bearing on the axes of rotation (P) are positioned on the said lock bearing (16).

[0084] FIGS. 7, 8 and 8A illustrate views of the movable lock (30) assembly applied to an earring or a bracelet worn on the wrist.