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Aluminium sand casting is a time-tested manufacturing process used to produce metal parts by pouring molten aluminium into a sand mold. It is especially valuable for producing components with complex shapes, internal cavities, and varying wall thicknesses — without the need for expensive dies or tooling.
Whether you're producing a single prototype or a batch of functional parts, aluminium sand casting offers an ideal balance of flexibility, cost-efficiency, and performance.
In this post, we'll break down the four essential steps of aluminium sand casting, explaining each stage in detail and highlighting what makes this process both effective and widely used.
Step 1: Pattern Making
The first step in the aluminium sand casting process is pattern making. A pattern is a model or replica of the final part that will be cast. This pattern is used to form the cavity in the sand mold where the molten aluminium will flow and solidify.
Key Details:
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Patterns are commonly made from wood, plastic, or metal.
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The design must account for shrinkage, as aluminium contracts slightly as it cools.
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In complex castings, additional tools called cores are created to form internal cavities or hollow sections.
Patterns can be reused multiple times, especially in mid-volume production. The accuracy of the pattern directly affects the quality of the final casting.
Step 2: Mold Making
Once the pattern is ready, the next step is to create the sand mold. This is done by placing the pattern in a molding box (flask) and packing it with a special type of foundry sand that holds its shape well.
The mold is typically divided into two halves:
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Cope – the top half
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Drag – the bottom half
After compacting the sand around the pattern, the pattern is carefully removed, leaving behind a cavity in the shape of the desired part.
Additionally:
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Gating systems (channels) are created to guide the flow of molten aluminium into the mold.
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Risers are added to allow air to escape and ensure complete filling of the mold.
This stage may also include inserting sand cores into the mold to form internal voids or passages within the part.
Step 3: Pouring Molten Aluminium
With the mold prepared, the next step is to pour the molten aluminium into the mold cavity. Aluminium is melted in a furnace at a temperature of around 660°C (1220°F) and then transferred to a ladle for pouring.
Key considerations:
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The pouring must be controlled to avoid turbulence, which can introduce gas pockets or defects.
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Foundries must carefully monitor temperature and flow rate for optimal casting quality.
Once poured, the molten aluminium fills the cavity and begins to cool and solidify into the shape of the final part.
Safety is critical at this stage due to the high temperatures involved. Foundry workers wear protective equipment and follow strict protocols during the pouring process.
Step 4: Cooling, Shakeout, and Finishing
After the aluminium has solidified, the casting is left to cool for a specified amount of time. Cooling time varies depending on the part's size, thickness, and complexity.
Once sufficiently cooled, the mold is broken apart in a process called shakeout, and the raw casting is removed.
Finishing processes may include:
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Removing gating and risers (usually by cutting or grinding)
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Surface cleaning to remove residual sand or oxides
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Machining for tight tolerances, holes, or threads
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Heat treatment to improve mechanical properties if needed
At this point, the casting can undergo inspection or testing, especially if it’s a critical component for aerospace, automotive, or industrial machinery.
Conclusion
Aluminium sand casting is a reliable, flexible, and economical method for producing high-quality metal parts. By understanding the four essential steps — pattern making, mold making, pouring, and finishing — manufacturers can optimize their designs, control costs, and ensure successful outcomes for both small and large-scale projects.
Whether you're building a prototype, replacing a legacy part, or producing small batches of components, aluminium sand casting remains one of the most effective solutions available in modern manufacturing.

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