3D Printing for Durable, Accurate Patterns
3D printing with FDM Technology offers a simple, fast and affordable alternative to machining spin casting patterns. Go from CAD to casting in hours instead of days.
Spin Casting With PolyJet or FDM Tooling
Spin casting uses centrifugal force to produce parts from a rubber mold. While spinning, casting material is poured into a mold, and centrifugal force pulls the material into the cavities. This accelerates production rates and preserves fine details for castings made of metal, plastic or wax.
In many ways, spin casting is similar to RTV (room temperature vulcanizing) molding. Both processes use rubber molds that reproduce crisp details and accommodate undercuts. Additionally, spin casting and RTV molding offer low–cost tooling and short lead times for part production. Yet, spin casting has some unique advantages over RTV molding.
Because it uses organic or silicone rubber that is heat vulcanized, spin casting molds can be ready for production in just a few hours versus one or two days. The properties of the rubber, combined with the spinning action, also result in extremely short cycle times. For some materials, parts are made in as little as 30 seconds. And a spin casting mold will usually have multiple cavities, so the short cycle time and multiple parts per cycle can yield fairly high production rates.
The heat vulcanized rubber molds can withstand high temperatures. This allows spin casting to manufacture parts in metals with a melt temperature that is less than 1,000 °F (538°C). The available alloys include zinc, tin, pewter and lead. For these metals, spin casting is the easiest, cheapest and fastest casting method. Spin casting is also an easy, affordable and fast process for making parts in thermoset plastics and foundry wax for investment casting.
Within hours of starting the mold making process, spin casting can churn out metal, plastic and wax parts at a rate of 1,000 to 10,000 a day. With multiple molds, this production rate can more than double. However, before mold making begins, patterns must be made. Traditionally machined from metal, due to vulcanizing temperatures and pressures, the patterns can add days to a process that can be completed in hours.
FDM and Spin Casting
Parts built on a Fortus 3D Production Systems using FDM technology address the need for fast delivery of durable and accurate patterns. By replacing the machined metal patterns, the entire spin casting process, including pattern making, can be completed in as little as one day. FDM is a viable pattern making option because its thermoplastic materials can endure the vulcanizing process. During vulcanization, the mold and its patterns are subjected to temperatures of 300 to 350 °F (149 to 177 °C) and pressures of 800 to 3,500 psi (5.5 to 24.1 MPa) for one to two hours. Fortus PC (polycarbonate) and PPSF (polyphenolsulfone) materials have performed under these conditions.
Like spin casting, FDM produces complex, intricate shapes with no impact on time or cost. Another similarity is the each is capable of producing multiple parts per cycle. These are not characteristics of machined patterns, and this is why FDM is a faster and more cost-effective solution. If a spin casting mold needs 25 patterns that have numerous features, including undercuts, a Fortus system can easily produce them in only a few hours. Another advantage of FDM that is not true of machining or spin casting is that the production process is laborless and automated. While casting parts from one mold, the Fortus system can be working in the background making patterns for the next project. With FDM, spin casting can produce thousands of metal, plastic or wax parts in a single day.
Molds are formed by placing patterns between disks of uncured rubber. The mold is then loaded into a vulcanizer that applies heat and pressure to cure the rubber. After a few hours, the mold becomes firm yet flexible. The mold is then loaded into a spin casting machine. After the spin cycle starts, the liquid metal, plastic or wax is poured into the rotating mold. Pressure caused by centrifugal force pushes the liquid through the mold’s runner system, completely filling each mold cavity. After the material has solidified, the mold is removed, and the castings are extracted.
A spin casting project begins with a mold layout and selection of pattern material. The layout of a spin casting mold will usually consist of multiple parts that are placed symmetrically around the center hub. A mold may be designed to create many copies of the same part or many different parts. This layout will determine the number of FDM patterns required.
Of all the Fortus materials, PC and PPSF are the best suited for pattern making. Due to the temperature and pressure applied to the mold during vulcanization, patterns constructed in other Fortus materials may warp and distort. In general, PPSF will produce the most accurate spin cast parts because of its high heat deflection temperature and mechanical strength. However, it also requires more time and labor for support removal and pattern preparation. PC is more easily finished, but it is slightly less stable in the vulcanizing process, which may translate to larger dimensional deviations.
FDM patterns can be made from a casting’s CAD data with no need for modification. Since the mold is pliable, draft angles do not need to be added to the design and small undercuts do not need to be removed. Optionally, shrinkage compensation can be added to the CAD data prior to exporting an STL file, but this can also be done within Insight.
The shrinkage compensation will vary with the rubber used for the mold and the material that is cast. Refer to supplier information and calculate the net shrinkage for the mold and castings. Scale the STL files by this shrinkage amount. In Insight, orient the patterns for the best surface quality and detail, and then select the solid build style. Any patterns constructed with sparse fi ll will be subject to collapse when exposed to the pressure of the vulcanizer.
After the build is completed, remove the support structures and finish the patterns to the desired quality level. Since the rubber molds will pick up very small details, it is import to smooth all surfaces to the quality level needed in the cast parts. To achieve the desired finish, use a combination of DCM (methylene chloride) dipping (PC only), sanding, filling and priming.
The spin casting mold begins as pre-formed, uncured rubber disks that have a consistency similar to modeling clay. The type of rubber—organic or silicone—is selected based on the material to be cast, type of part and desired production quantities.
The rubber disks are stacked to the desired thickness for the core side of the mold. The patterns are then arranged in a balanced, symmetrical pattern to ensure even material distribution. Each pattern is then aligned such that material can be easily pulled through the cavity. Typically, this orientation has the longest side of the part along a radial line from the hub.
Once placed and aligned, the patterns are then embedded in the rubber to define the parting line for the cast part. For flat bottomed parts, the patterns are laid on top of the rubber. For all others, a shallow pocket is cut into the rubber. The pattern is then set into the pocket, and the excess rubber is shaped around it to establish the parting line.
Next, insert a center plug into the middle of the rubber disc to create the sprue. Then arrange locknuts or pins on the perimeter to ensure proper alignment of the two mold halves when assembled for casting. Optionally, preforms for the runner system may also be placed into the mold. The core side of the mold is now complete. Place the core side in a circular mold frame, and spray the surface with mold release. To complete the mold, stack additional uncured rubber discs on top of the core side of the mold. This will be the cavity side of the mold.
The vulcanizer consists of two heated platens mounted on a hydraulic press. The heat and pressure of the vulcanizer cause the uncured rubber to flow around the patterns and fill the voids. As the exposure to elevated temperatures continues, the rubber begins to cure, which causes it to become firm yet flexible.
The uncured rubber mold containing the patterns is placed into the vulcanizer, which is preheated to 315 °F (157 °C). The pressure is then slowly raised to approximately 1,000 psi (6.9 MPa) to squeeze the halves of the mold. The pressure and temperature, which vary by type of rubber, are maintained for one to two hours.
When vulcanizing is complete, the mold is removed. After a short cooling period, the mold frame is taken off, and the two halves are separated. The patterns, and any metal preforms, are then extracted from the mold. Gates, runners and vents are now cut into the cured rubber with a sharp knife or scalpel. Typically, each is a V-shaped channel. The gates and runners feed casting material to the part cavity from the central hub. The vent allows air in the cavity to escape so that back pressure does not cause a partial fill of the mold cavity. The mold is now ready for spin casting.
Apply mold release to both sides of the rubber mold, close the mold and place it in the spin casting machine. Prior to starting the spin casting machine, prepare the casting material. If casting metal, melt the material in a gas or electric furnace. Bring the molten alloy to the ideal casting temperature. If the metal is too cold, it will freeze off before filling the mold, and if too hot, it will degrade the mold prematurely. When casting foundry wax, melt the material in a suitable melting tank or pot. For thermoset materials, combine the two parts of the material kit and stir thoroughly.
To prepare the spin caster, select the rotational speed, clamping pressure and cycle time. Each variable will be dependent on the material that is cast. For example, metals will have a cycle time of less than one minute, while plastics will have a duration of five to 10 minutes.
Start the spin caster, and as the mold is spinning, pour the casting material into the funnel at the top of the machine. When the cycle is complete, remove the mold from the spin caster.
Separate the two halve of the rubber mold to expose the castings. To extract them, fl ex the rubber or gently pry the casting from its cavity. If any material remains in the gate, runner or vent channels, remove it prior to reusing the mold. Finish the casting by snapping the gates off of the part and grinding or sanding the remainder. The castings are now ready for painting, plating or use.
For metal, plastic and wax parts, spin casting is a simple, affordable and fast method for prototyping or production. With FDM, the same can be said of the pattern–making process. Within hours, molds can be made and parts can be cast.
Tools Without Tooling
3D printed tools, molds and tool masters add a new layer of cost efficiency and flexibility to the factory floor. Not only can you cost-effectively produce tools for prototype testing and manufacturing low volumes of final parts, you can create made-to-order assembly tools customized for each task. In addition, you can create a leaner manufacturing environment, enabling quick production of tools, when and where they’re needed to speed the manufacturing process and reduce costs.
Optimized assembly tools, made to order
Improve manufacturing efficiency with job-specific jigs and assembly fixtures, 3D printed on demand in just hours. 3D printing tools directly from CAD data, on-demand, saves time, lowers costs and reduces inventory requirements. In addition, you can easily create customized lightweight, ergonomic tools that increase workflow efficiency.
3D printed Injection molds
Imagine producing injection molds without costly CNC tools. With Stratasys thermoplastics and photopolymers, you can quickly 3D print injection molds to evaluate prototype parts or produce low volumes of end use parts. This is especially useful to test the design, fit and function of products before mass production. If changes are required, new mold iterations can be 3D printed in just a few hours at minimal cost.
3D print customized, low volume durable parts with fine details and smooth surface finishes
Stratasys additive manufacturing enables you to 3D print strong, functional final parts on demand directly from CAD data. Because the part is created digitally layer by layer, complex geometries and sophisticated features that would be difficult to produce using traditional manufacturing methods are now easily achieved with Stratasys additive manufacturing. Producing end use parts with Stratasys technology not only dramatically reduces your production costs and delivery times, it also reduces inventory while creating exciting new supply chain efficiencies and new business models.