May. 12, 2025
Vacuum casting uses silicon moulds to make a high-quality prototype of plastic and rubber components using two-component polyurethanes resins
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Vacuum casting, sometimes referred to as Urethane casting or Polyurethane casting uses silicone moulds to make plastic and rubber components under vacuum. It is an extremely adaptable manufacturing process capable of mimicking the injection moulding to produce complex parts in polyurethane resins and cast nylon.
Due to the process being under vacuum, it produces high-quality bubble-free casting with smooth surface texture without any blemishes.
Vacuum casting can be extremely useful in rapid prototyping injection moulding parts and worth considering when selecting rapid prototyping processes for plastic or rubber parts.
Vacuum casting works in a similar way to traditional injection moulding where it requires a mould tool with a part shaped cavity. Where injection mould tools are made from metal (steel, aluminium etc), vacuum casting uses soft silicone moulds.
Like most of the manufacturing processes in this modern era, the process begins by 3D modelling the required shape or 3D geometry. As a rule of thumb, products designed for vacuum casting must follow injection moulding design guidelines, to achieve better results. Sometimes, the parts can be inspected using 3D laser scanning which can create and output 3D files.
The master pattern is then created from the 3D CAD model. Although they were traditionally made using CNC machining or handcrafted, these days it is much quicker to use additive manufacturing. 3D printing techniques such as SLA or SLS are most suitable and cost-effective as the pattern maker.
But, if you have a cast model which can be used as the master pattern then it can be used directly. However, note that the patterns must be able to withstand temperatures up to 40°C.
Sometimes, metal inserts are used to hold tight tolerances in bores and critical areas.
Then, the parts are hand finished manually by cleaning and creating the required surface finish. Surface textures such as gloss and matt can be achieved by painting/spraying the master pattern.
Next, a silicone mould is created using the master pattern.
Casting polyurethane resins are generally preheated to about 40°C before the mixing stage. A two-component casting resin is then mixed in exact proportions including any coloured pigment and poured into the bowl inside the machine. The mould is then returned and pouring gates are connected to the mixing and pouring bowl.
During the auto pouring process, the casting resins and the colour pigment are fully stirred and deaerated for 50-60 seconds under a vacuum. Then, the resin is poured into the mould under a vacuum to avoid any air pockets or voids. Vacuum ensures bubble-free moulds and removes any resistance to flow caused by pockets of air inside the tool and the filling of the tool takes place by gravity feeding alone.
When the resin has been cast, the mould is then placed in a heating chamber to cure. Once cured the casting is removed from the mould. Next, the gate and risers are removed from the casting and any additional finishing is carried out.
The following video illustrates the method of mixing and poring inside Renishaw’s vacuum casting machine.
Video content credit – www.renishaw.com
Vacuum casting and Injection moulding are similar processes that can create identical plastic parts using similar materials. However, in contrast to urethane casting, which relies on gravity to fill the moulds, injection moulding employs a pressured nozzle to push the molten plastic into the mould cavity.
The following are the primary factors to consider while picking between urethane casting and injection moulding.
Initial cost – Because injection moulding uses metal moulds, they are much more costly than urethane casts. Hence injection moulding is better suited for production-grade mass batch manufacturing. On the other hand, urethane casting moulds are cheaper, saving you money upfront. As a result, it is better suited for one-off designs, low-volume productions or pre-production prototypes.
Material cost – The production-grade plastic required for injection moulds is significantly more costly than Urethane. PVC, ABS, acetal, and LPDE are examples of such injection moulding materials. Therefore, Urethane is the preferable material for prototypes and low-volume production.
Per-part cost – The per-part cost for Urethane is usually greater than for injection moulding. This is because each mould can only produce a certain number of pieces. On the other hand, injection moulding produces far larger volumes, making it cheaper. This lowers prior higher expenses, like materials and tools. In this regard, injection moulding is typically the most cost-effective moulding method for long-term manufacturing.
Urethane is suitable for prototypes because of its lower upfront costs and shorter lead times – unless injection moulding is required. For larger product runs, injection moulding provides a considerably greater ROI, and the steel moulds used last significantly longer than their silicone counterparts.
Moulds for injection moulding can take a long time to produce because they are made using metal, increasing product development duration. Urethane silicone moulds are easier to produce. They can usually be made with a 3D printer or even by hand, decreasing lead times and allowing you to get your product to market faster.
Vacuum casting can be utilised for prototypes, bridges, and low-volume manufacturing of one to hundreds of pieces.
Injection moulding can be used for prototypes or bridges, but it is most commonly employed for high-volume manufacturing of hundreds to tens of thousands of units.
Urethane’s tolerance is +/-.010″ for the first inch and +/-.005″ for each inch after that. Likewise, injection moulding tolerances are +/.005″ for the first inch and +/-.002″ for each inch after that.
Product designers and engineers often turn to 3D printing for design validation, and make the immediate leap to injection molding for production validation. But the problem is that the cost of an injection mold, made out of CNC machined high-grade steel and good for millions of parts, can cost between $5,000 and $100,000 depending on part size and complexity.
That’s why lower-grade tools are often used as an intermediate step to hard tooling. An aluminum mold still ensures up to 1,000-5,000 molding cycles at a much-reduced cost. Because soft tooling processes are much faster and allow for a simplified mold design, they also roughly halves the lead time when compared to injection molding.
An acrylic mold or low-volume injection molding with 3D printed molds can be an option, depending on the quantities and part quality needed. A 3D printed mold created with a Formlabs SLA printer typically costs under $100 and delivers 100+ pieces without significant loss of quality.
However, product developers regularly overlook the fact that vacuum casting is often a smarter approach to cross the bridge from prototyping to production. Of all early-stage prototyping methods, the resin casting process bears the most similarities to injection molding. Additionally, it’s highly cost-effective; molds cost between $200 and $1,000, and a typical per-unit price is $10-$100.
A silicone mold for urethane casting is constructed in a similar fashion to an injection mold in that it has two halves—one forming the core, the other the cavity, and the liquefied material is injected in between those to form the final product. However, there are a few differences:
In injection molding, molten polymer is pushed into the mold cavity under high pressure and high temperature using a hopper and lead screw. Vacuum casting operates at low temperatures. Instead of molten plastic, it works with liquid resins that are drawn into the mold under a vacuum, much like the capillary action inside a plant stem. So while there are many different resins available to mimic various polymers, prototyping in the final injection-molded material is not possible.
After oven-curing, parts still undergo some post-curing for up to a week and remain vulnerable to UV radiation and high temperatures.
Because the mold is flexible, there are limits to part size and shape. Still, there are specific techniques to enable exceptions. For example, phased casting is the use of metal supports to counteract gravity for casting elongated parts in a three or four-part mold.
Vacuum casting handles variable wall thickness better than injection molding, because there is no heating-cooling cycle of the cast material. This results in less part distortion.
A silicone mold allows for significant undercuts in the part design. However, when testing for injection molding, it’s recommended to stick to the injection molded design as much as possible and build in the required draft angles of the final product.
Vacuum casting results in nearly zero waste, whereas in injection molding up to 20% of the used polymer is lost due to scrap rates, residues, and overproduction.
The high fidelity between a vacuum-cast model and a final product that pops out of an injection mold allows engineers to optimize the design for manufacturing. It provides them with a high-quality product preview without having to burden upper management with the astronomical fixed costs that can come with contract manufacturing at an injection molding factory.
It is a common misunderstanding that 3D printing is restricted to one-offs only. On the contrary, it is a viable method for low volume manufacturing of end-use parts. It is also increasingly popular for companies to invest in an in-house print farm. Such an array of 3D printers can handle low-volume batches of hundreds or even thousands of products.
The main factor influencing a choice between 3D printing and vacuum casting is product geometry. Vacuum casting is explicitly intended to simulate injection-molded parts. As a low-investment alternative to full-scale injection molding, it can even combine flexible and rigid materials in an overmold or add metal components directly in the prototype through insert molding. For creating a small series of injection-moldable components, vacuum casting is more cost-effective than 3D printing.
Another advantage of vacuum casting is that bigger parts can be created much faster and cheaper than 3D printing. It allows for mold sizes of roughly 50 cm (20 inches) for the longest dimension, and casting weight up to 1.5kg (3.3 lbs).
The master pattern is the positive model from which the copies will be derived through casting. Because a silicone vacuum casting mold delivers the exact replica of the master pattern, it is paramount that the 3D printed pattern accurately embodies the original CAD model, especially in terms of ultra-smooth surface quality. Some secondary characteristics of a good master pattern are hardness, chemical and temperature resistance, as well as durability to prevent degradation over time.
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CNC-milled master patterns used to be the standard, but they are costly and time-consuming to produce. They also come with limitations regarding holes, channels, internal radii, and organic surfaces. 3D printing is the cutting-edge alternative and currently prevailing method for producing master models.
There are multiple 3D printer types available to both mainstream and commercial customers, but the most commonly used processes for urethane casting are SLA and SLS 3D printing.
SLA 3D printing produces parts with the smoothest surface finish, which is ideal for vacuum casting patterns. While SLA prints are already smooth with the right print settings, they will still require some sanding and polishing to remove supports and achieve an absolutely flawless finish. Some advanced materials like Rigid 10K Resin also offer superior mechanical properties, temperature resistance, and durability.
SLS 3D printing with nylon results in strong, temperature-resistant, and precise prints. As this technique doesn’t require supports, it’s also ideal for intricate features like thin walls, engraved details, snap fits, hinges, and nested or interlocking parts. The surface finish of printed parts is a bit too coarse for printing master patterns for urethane casting, so SLS 3D printed parts can benefit from media blasting or vibratory tumbling to reduce surface roughness.
In this most labor-intensive stage of the process, the model maker crafts a mold box out of melamine board and hot glue. They then secure the master pattern to the bottom with small drops of CA-glue. Sometimes, pockets are created using a rotary tool where lips designed onto the master model will fit into for extra fixation.
For a tight parting line between the two mold halves, all holes between the master pattern and the bottom panel need to be filled up. Styrene blocks and Plastalina modeling clay are preferred materials to do this. Then, add dowel pins and registration bars for perfect alignment with the other mold half.
After vigorously mixing the two-component silicone, it is poured and degassed inside a vacuum chamber. But before doing so, the model maker craftily fills up all tiny gaps in the master pattern with the silicone mixture using an acid brush in order to prevent air traps, and then back-pours the silicone to form the first half of the mold.
After curing for several hours, the mold half is released from the mold box and flipped upside down. The mold maker expertly installs acrylic vents, risers, and a fill port for the second half of the process. Spray mold release on top of the silicone and brush it inside deeper areas. Then, a new mold box is constructed for pouring the second mold half in a similar fashion.
To prepare the mold for vacuum casting, release it from the mold box and spray it with an even coat of E236 urethane mold release. Recombine the mold halves to form a single block, and reinsert the dowel pins and registration keys for alignment.
In this step, the original master pattern is replicated through casting in a vacuum chamber. First, the mold is taped to a wooden board and vent straws plus a pouring funnel are added to it.
The two-component resin is measured and mixed with a coloring agent for pigmentation. Then, the casting material is degassed in a vacuum chamber for a few minutes.
The polyurethane blend is now ready for pouring. The riser straws will indicate when the cavity is completely filled up. After curing at 70˚C, the mold is opened to reveal a carbon copy of the original model with all details and surface textures preserved.
The finalization consists of trimming the edges of flash material, an extra polishing cycle with -grit sandpaper, and oven-curing to improve the part’s material properties.
Due to the complexity of the process, most companies subcontract jobs to third-party urethane casting service providers.
For those planning to do vacuum casting in house, a professional vacuum casting machine provides an integral solution for taking prototyping efforts to the next level and speeding up the process towards production ramp-up. As much as fifty castings can be achieved within two days, each in a different material and color if needed.
A vacuum resin casting machine is a refrigerator-sized contraption that automates the process from mixing to casting to curing. It lets operators control parameters such as chamber pressurization, mixer speed, heated cup, and oven heat. The latest systems are programmable so that operators can create custom sequences to optimize casting cycles for specific materials and product types.
Vacuum casting machines come in different sizes to allow for different mold sizes. Most models can, next to working with resin, also be set up for casting injection-grade nylon, ceramics, wax, and even low-melt metal alloys.
Urethane casting machines are ideal for pre-production runs because they pull a vacuum much quicker and minimize manual labor. The downside is that they cost tens of thousands of dollars. Jewelry vacuum casting machines are much smaller and generally cost a few thousand dollars.
Here are some of the best vacuum casting machines:
Renishaw 5/01 PLC: Max. mold size 530 x 450 x 420 mm, price roughly $45k. The larger 5/04 model allows molds up to 750 x 750 x 900 mm and more materials, like glass-fiber reinforced nylon and wax, but it comes at nearly double the price.
SLM VCM 04: Max. mold size 750 x 750 x 900 mm, casting volume 2.2L, and includes casting with nylon and wax.
MCP 5/01: Max. part size 400 x 400 x 400 mm. MCP offers many larger models, including the MCP 003 with 560 x 600 x 600 mm part size, the 4/04 with 900 x 750 x 600 mm part size, and the 4/05 with x 750 x 800 mm part size. These machines are fully programmable and allow vario-pressure casting with wax, silicone, and nylon, next to PU resins. They can also be used with 3D printed injection molds.
Scott AM : Max. mold size 500 x 450 x 425 mm, 1 kg casting weight. The model has a max. mold size of 750 x 750 x 900 mm and 5 kg casting weight. Besides resins, these apparatuses can be used for vacuum investment casting with ceramics and metals.
Multistation CSV 340: Max. mold size 340 x 340 x 435 mm, casting volume 600 mL. The CSV500 model fits molds up to 500 x 500 x 635 mm and casting volumes up to 1 liter.
For a low-budget alternative, it is entirely possible to build a homemade vacuum gravity casting machine. Since a single air bubble left inside the mold can ruin the entire casting, degassing is a fundamental challenge of the resin casting process.
To get all bubbles out of the mixture, there are two anti-bubble weapons of choice when it comes to building a DIY vacuum casting machine: a vacuum chamber or a pressure pot.
A vacuum chamber is a vat that can be used to remove the air from silicone rubber before creating the mold. Because the vacuum-pulling approach is slower than the high-pressure approach, a vacuum chamber only works with slow-setting resins that have a curing time of twenty minutes or more.
A vacuum chamber has two levers: one for the air inlet, and the other for the vacuum pump. It has a gauge for checking if the vacuum has been reached, and a transparent acrylic lid for checking the degasification. A tempered glass lid is well-worth the higher price since it will never crack over time, as opposed to a plastic lid.
Pressure pots cost a bit more since they require an air compressor. But on the other hand, they are arguably the best means to create bubble-free resin mixtures and castings. Unlike vacuum chambers, these can be used with the mold, they work with quick-setting resins that have a short working window, and the resulting castings will be 100% clear of trapped air.
A vacuum chamber has the advantage of being useful for many applications, like deairing plaster, concrete, or wood infusions, while a pressure pot will typically only be utilized for degassing batches of silicone.
Casting silicones can be divided into tin-cure and platinum-cure silicones. Tin-cure silicones, a.k.a. condensation-cure silicones, show between 1-4% shrinkage. While model makers will do their best to compensate for shrink rate, for high-tolerance applications it’s better to go with higher quality platinum-cure silicone or high-temperature vulcanization (HTV) rubbers.
A 40-50 Shore A hardness will make for a durable mold that can be reused dozens of times, while facilitating easy demolding, even for parts that would get locked inside a rigid mold because of backdraft issues. A translucent silicone is recommended because it provides visibility of air traps, bubbles, contaminants, and everything else that’s going on inside the mold.
Some great two-component silicone brands are SmoothOn, Elastosil, V-Sure, and Silicones and More (S.A.M.). Ordering directly from chemical factories overseas can also reduce the price while providing a professional-quality product according to the buyer’s exact specifications, especially for large orders.
The team at Louisville Slugger Innovation Center found that little things can make a big difference. They have been producing baseball bats since and know all about the factors that create an ever-faster, more powerful swing.
The staff at the Slugger Innovation Centers have maintained an analytic approach to design for sports, and created a grip add-on with help of Formlabs 3D printing solutions. The stepped geometry aids batters in acheiving a perfect grip for the firmest possible strike.
As in other cases, the Slugger design team found that having 3D printing and vacuum casting capacity on board under one roof speeds up the design iterations while driving faster knowledge generation. Detailed prototype models, printed on a Form 3 SLA printer at 50 μm layer height, served to create a mold positive. The power of urethane casting enabled them to create durable, testable models that near the quality of a silicone injection molded final product.
SiOCAST has a unique story to tell when it comes to integrating 3D printing with resin casting. With the rise of MMORPG online games as well as RPG board games has come a rapidly growing demand for custom miniature figurines. Instead of going for the costly route of spin casting, or the limited series allowed with vacuum casting silicone molds, the company developed a patented resin injection system that works with a custom-developed machine and HTV rubber molds.
Their proprietary material, SiOres, even works with liquefied thermoplastic resins up to 240 ˚C. A SiOCAST machine is up to twenty times faster than traditional resin casting and could produce as many as 1,000 parts per hour with automation and rotating multi-cavity molds.
All master patterns are 3D printed using a Formlabs SLA printer and post-processed with Formlabs’ automated cleaning and curing systems, Form Wash and Form Cure. With reusable runners produced through SLS 3D printing, the process is further sped up to create up to 64 miniatures per casting.
Where injection molding produces the occasional error because it has to deal with more critical conditions and viscous materials, these vacuum cast models are without exception impeccable replicas of the original sculpture and ready to satisfy the digital soul of many a gamer.
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