Intricate Geometric Inlay Ring JDBCo 3D print model

Chic Ring With Intricate Geometric Inlays And Beaded Accents
Ready To Print 3D-Model For Jewelry Manufacturing.

Elevate your style with our stunning ring featuring intricate geometric inlays and refined beaded accents. This sophisticated design is perfect for those who appreciate fine craftsmanship and artistic details. The precise inlays create a visually captivating pattern, while the subtle beads add an extra touch of elegance. Ideal for both everyday wear and special occasions, this ring will effortlessly enhance any outfit. Its unique blend of modern aesthetics and timeless beauty makes it a must-have addition to your jewelry collection.

Designed by JDBCo

Model details:
(calculated)

Model file: model_main.stl
Size X: 21.660 mm
Size Y: 7.200 mm
Size Z: 21.661 mm
Polygons: 27482
Vertices: 13741
Volume: 423.394 mm³
Surface Area: 1442.260 mm²

Weights in materials:
(calculated)
Platinum: 9.06 g
Gold 18K: 7.16 g
Gold 14K: 5.42 g
Silver: 4.45 g

Our jewelry designs can generally be produced with any of the following metals: gold (yellow, white, rose), silver, platinum, other metals.

Actual sizes and weights may vary from the calculated values.

Our jewelry designs can generally be manufactured using the following primary methods:

1. 3D Printing (Additive Manufacturing)

• Method: Using 3D printers with materials like PLA (Polylactic Acid), resin, wax, plastic, or metal.
• Applications: Creating detailed prototypes and final models. High precision, capable of producing complex geometries.
• Materials: PLA for easy printing and eco-friendliness, resin for high detail and smooth surface finishes, wax and plastic for prototyping, metal for final pieces.

2. Investment Casting

• Method: Creating a wax model via 3D printing or CNC machining, then casting metal.
• Applications: Producing high-quality metal pieces suitable for mass production. Uses 3D printed models made from PLA, resin, or wax.

3. CNC Machining

• Method: Using computer-controlled machines to cut and shape metal.
• Applications: Producing precise and larger items. Suitable for complex designs and high precision.
• Materials: Metal for final products.

Also, possible to use the secondary methods:

4. Electrical Discharge Machining (EDM)

• Method: Shaping metal using electrical discharges.
• Applications: Creating very complex shapes with high precision.
• Materials: Metal for detailed and intricate designs.

5. Laser Cutting and Engraving

• Method: Using lasers to cut and engrave materials.
• Applications: High precision cutting and engraving for various materials, fast processing.
• Materials: Metal, plastic, and other suitable materials for detailed cuts and engravings.