Castable Wax Ultra HD

Solidscape Midas

Solidscape® 3Z Model is the most detailed and precised castable material in market. The strength is also reinforced to enable the highly complicated stuctures.

Min. Order Value $25

Est. Lead Time 4 days

Max Build Size

152 x 152 x 50 mm

Min Build Size

1 x 1 x 1 mm

Default Layer Height

0.016 mm

Optional Layer Heights

0.016, 0.032 mm

Tolerance

±0.1 mm

Heat Endurance

Up to 40 ℃

Smooth ★★★★★

Detail ★★★★★

Accuracy ★★★★★

Rigidity ★★★

Flexibility ★★

Available Colors

Skyblue

Available Post Process

Gallery

Suitable For

Complex designs with intricate details,
Fine-detail models with smooth surfaces,
Sales, marketing and exhibition models,
Jewelry, art

Not Suitable For

Cases, holders, adapters,
Large models,
Functional prototyping and testing

Additional Info

Solidscape 3Z Model is the build material for 3D printing jewelry and other non-dental applications.

Model is Solidscape’s most durable material ever with a 23% strength improvement over plusCAST® and over 50% stronger than previous generations. This increased durability enables designers to incorporate even more intricate details with thinner walls into their work to produce lighter weight finished products that can meet their pricing strategy.

For customers looking for 3D printer companies with wax materials that are created specifically for their rapid prototyping machines, Solidscape is your first choice.

Min Supported Wall Thickness A supported wall is one connected to other walls on two or more sides.	0.3 mm
Min Unsupported Wall Thickness An unsupported wall is one connected to other walls on less than two sides.	0.6 mm
Min Supported Wires A wire is a feature whose length is greater than five times its width. A supported wire is connected to walls on both sides.	0.3 mm
Min Unsupported Wires A wire is a feature whose length is greater than five times its width. An unsupported wire is connected to walls on less than two sides.	0.8 mm
Min Hole Diameter The accuracy of a hole not only depends on the diameter of the hole, but also on the thickness of the wall through which the hole is printed. The thicker the wall section, the less accurate the hole becomes. Through holes must also allow for line-of-sight clearance to ensure all material is cleared during post-processing.	0.8 mm
Min Embossed Detail A detail is a feature whose length is less than twice its width. The minimum detail is determined by the printer’s resolution.When detail dimensions are below the minimum, the printer may not be able to accurately replicate them. Details that are too small can also be smoothed over in the polishing process. To ensure details come out clearly, make them larger than the indicated minimum. We may refrain from printing products with details smaller than the minimum, since the final product will not be true to your design. If your product has details smaller than the minimum, try making them larger, removing them, or considering a material with finer detail.	0.1 mm
Min Engraved Detail A detail is a feature whose length is less than twice its width. Engraved or debossed details go into a surface.	0.1 mm
Min Clearance Clearance is the space between any two parts, walls or wires. To ensure a successful product, make the clearance between parts, walls, and wires greater than the indicated minimum. If your clearance is too small, try making the gap bigger, or consider fusing the parts or features if their independence is unnecessary. You can also try a material with a smaller minimum clearance.	0.2 mm
Min Escape Holes Escape holes allow unbuilt material inside hollow products to be removed. Normally you don’t need to consider this, our technician will add escape holes before printing. When products contain hollow cavities, they are often filled with powder/liquid even after they are removed from the build tray. If escape holes are not large enough, or the geometry of the product makes it difficult to shake or blast the powder out, we cannot successfully clean it.	4 mm
Interlocking/moving or enclosed parts? Sometimes the interlocking/moving parts can’t be printed, since the supports inside the cross section can’t be removed.
Require Support Material? Because each layer needs to build off the last, for some material, angles of more than 45 degrees generally require supports to be printed along with the design. Supports are not inherently detrimental for your design, but they do add complexity to the printing process and lead to less smooth finish on overhanging parts.	Yes

Feature

Watertight	Foodsafe	Glueable	Recycleable

Biocompatible	Biodegradable	Flame Retardant	Conductive
Untested	Untested

3D Printer

Solidscape-3Z Studio

Material Spec Sheet

Castable Wax Ultra HD is 3D printed using Wax Jetting (Wax 3D printing) technology.

Wax 3D printing and lost-wax casting are used to build your design when using this material. The wax printing process is a type of Stereolithography/Multi material jetting that uses a wax-like resin. Support structures are printed along with the model to make sure your model doesn’t fall apart. These support structures are automatically generated and manually removed after the printing process. After support structures are removed and your model is cleaned, the model can be prepared for casting.

First, one or more wax sprues will be attached to your model. Next, the sprue and model will be attached to a wax ‘tree’, together with a bunch of other models. The tree is then placed in a flask and covered in fine plaster. When the plaster solidifies, it forms a mold for copper casting. The plaster mold is then put in an oven and heated for several hours to a point where the wax is completely burned out.

Then, molten copper is poured in to fill the cavities left by the wax. Once the copper has cooled and solidified, the plaster mold is broken and the copper models are removed by hand. Then, your model is filed and sanded to get rid of the sprues, and finally polished.

How is Wax Jetting 3D Printing Working?

Castable Wax Ultra HD