Skip to content

Die Casting Services | Custom Parts with Exceptional Accuracy

A masterful blend of detail and scale, die casting creates uniformly exquisite components across industries. Its hot and cold chamber techniques exemplify precision in mass production.

Discover the essence of this essential manufacturing art.

Let’s embark on a journey through the core mechanics of die casting, exploring its steps, suitability, and the subtleties of its machinery.

What is die-casting?

Die casting is a metal casting process in which molten metal is subjected to high pressure within a mold.

The mold is usually made of a stronger alloy that is machined to create the desired shape. This process is similar to injection molding.

Die casting is suitable for the mass production of large quantities of products, especially for producing complex-shaped small to medium-sized castings.

Die castings typically have high surface flatness and dimensional consistency.

Die-Casting
Die-Casting

Detailed Steps of Die Casting

  • Melting: The selected metal material is heated to a liquid state and maintained at an appropriate temperature.
  • Injection: Liquid metal is rapidly filled into the cavity of the mold under the action of high pressure through the injection system.
  • Cooling: The metal solidifies and cools in the mold to form the final shape of the casting.
  • Demolding: After cooling, the mold opens, and the casting is removed.
  • Post-processing: The casting may require subsequent processing steps such as removing the pouring gate, polishing, and heat treatment to meet the requirements of the final product.

Hot-chamber die casting vs cold-chamber die casting

Die casting machines are mainly divided into hot chamber die casting machines and cold chamber die casting machines.

Hot chamber die-cast machine

The hot chamber die casting machine is characterized by its press chamber integrated with the furnace, usually immersed in liquid metal.

This design allows the metal to go directly from the furnace to the press chamber without additional feeding processes.

A hot chamber die casting machine is suitable for the production of zinc alloy, magnesium alloy, and other low melting point materials casting.

They usually have a high degree of production efficiency and automation,

but because the pressure chamber and injection punch have been in a high-temperature environment for a long time, the service life may be affected.

Cold chamber die-cast machine

The press chamber of the cold chamber die casting machine is separate from the furnace, and the metal is scooped from the furnace and poured into the press chamber of the die casting machine.

This type of die-cast machine is suitable for the production of castings of high melting point materials, such as aluminum alloys, copper alloys, etc.

Cold chamber die-cast machines typically require higher injection pressure and energy, but they can provide better metal purity and longer mold life.

Cold chamber die-cast machines are more common in industrial production, especially in the production of aluminum alloy die-cast.

Each of the two types of die-cast machines has advantages and limitations, and choosing the right type of die-cast machine depends on the casting material required to be produced,

the production volume, and the specific process requirements.

What are the advantages and disadvantages of die-cast?

Advantages of Die Casting

  1. High Precision and Accuracy: Die casting offers excellent dimensional accuracy and consistency, producing parts with tight tolerances.
    Complex shapes and intricate details can be achieved without requiring additional machining.
  2. Cost-Effective for Large Production Runs: Once the die is made, the process is highly repeatable, making it ideal for mass production.
    Large volumes of parts can be produced efficiently, lowering the per-unit cost.
  3. Fast Production Cycle: Die casting has a rapid production cycle, with each casting process taking only seconds to minutes, allowing for high throughput.
  4. Smooth Surface Finish: Die-cast parts generally have a smooth surface finish, which reduces the need for secondary operations like polishing or machining.
  5. High Strength and Durability: The parts produced are dense and strong, as die casting results in parts with fewer internal defects and porosity.
    The pressure involved in the process improves the mechanical properties of the material.
  6. Versatile Materials: Die casting supports a variety of non-ferrous metals, including aluminum, zinc, magnesium, and copper,
    allowing manufacturers to choose the best material for their specific application.
  7. Minimal Material Waste: Die casting is highly efficient, producing very little material waste compared to processes like CNC machining, where a lot of material is removed during shaping.
  8. Complex Geometries: This process allows for the production of highly complex, detailed, and thin-walled parts that would be difficult to achieve through other manufacturing methods.
die-casting parts
die-casting parts

Disadvantages of Die-Casting

  1. High Initial Tooling Cost: One of the biggest drawbacks is the high cost of creating the die. This makes die casting less cost-effective for small production runs or prototypes.
  2. Limited to Non-Ferrous Metals: Die casting is generally limited to non-ferrous metals like aluminum, magnesium, and zinc.
    Ferrous metals, such as steel or iron, are not suitable for this process due to their high melting points.
  3. Porosity and Voids: Air or gas can become trapped during the injection process, leading to porosity or small voids within the part, which can weaken the structure.
  4. Size Limitations: The size of the part is restricted by the size of the die and the machine. Die casting is generally better suited for smaller to medium-sized components.
  5. Material Brittleness: Some die-cast materials may exhibit brittleness, which limits their ability to withstand heavy mechanical loads or harsh conditions compared to forged or machined parts.
  6. Secondary Operations May Be Required: Despite the high precision, some parts may require secondary finishing or machining to meet very tight tolerances or specific surface quality requirements.
  7. Not Ideal for Prototyping: Due to the high tooling cost and setup time, die casting is not suitable for prototyping or small production runs.
    It’s best suited for mass production where economies of scale come into play.
  8. Temperature Constraints: Die casting is limited to metals with lower melting points because the molds are typically made of steel. Extremely high-melting-point materials would damage the mold.

Considerations for die-casting materials

Manufacturers must consider certain factors and variables when choosing die-cast materials. These include:

  • Whether the material is suitable for hot-chamber die-cast
  • Material costs
  • Indirect materials costs (e.g. any extra post-processing required)
  • Material structural properties
  • Strength
  • Weight
  • Surface finish
  • Machinability

All of these factors should be considered when choosing a die-casting material for parts or prototypes.

The requirements for materials vary depending on the application, so the material selection must be based on specific usage conditions and performance requirements.

Classification and application of die-casting alloys

Die-casting alloys refer to various metal materials used in the die-cast process, which can fill the mold cavity under high pressure and high speed, and form accurate castings after cooling and curing.

Die-cast alloys mainly include aluminum alloy, magnesium alloy, zinc alloy, and copper alloy.

Each type of alloy has its own unique physical and chemical properties and is suitable for different industrial applications.

Aluminum alloy die-cast 

Aluminum die-cast alloys are favored in automotive, electronics, and consumer goods for their low density, high thermal conductivity, strength, and corrosion resistance.

Their lightweight enhances fuel efficiency and cuts emissions, crucial for automotive applications.

These alloys offer a good surface finish and can form complex shapes, ideal for mass production.

Aluminum Die Casting for Engine Blocks
Aluminum Die Casting for Engine Blocks
  • ADC12: This is an aluminum-magnesium alloy, with good fluidity, high hardness, strong corrosion resistance, and good processing properties.
    It is suitable for the manufacture of various structural parts and body shells.
  • A384: This is a high-strength die-casting aluminum alloy, with high strength, rigidity, and good heat resistance, suitable for manufacturing auto parts and mechanical structures.
  • A413: This aluminum alloy has moderate strength, good plasticity, and strong corrosion resistance,
    which is suitable for the automotive industry and the field of structural parts manufacturing.
  • AK5M2: This is a kind of high hardness, high strength die-cast aluminum alloy, with good wear resistance, suitable for automotive parts, aircraft and rail transit, and other fields.
  • YL113: This is a kind of high-strength die-cast aluminum alloy independently developed and produced in China,
    with good corrosion resistance, wear resistance, and mechanical properties, suitable for aerospace, automotive engines, and other fields.
  • YL102 (ADC1) and YL104 (ADC3): These are aluminum-silicon alloys with good casting and mechanical properties, suitable for the manufacture of a wide range of die castings.
  • YL112 (A380), YL113 (ADC10), and YL117 (ADC14): These are aluminum-silicon-copper alloys with high strength and good heat resistance, suitable for the manufacture of demanding die castings.
  • ADC6: This is an aluminum-magnesium alloy, compared with ADC12, its corrosion resistance is better, but it is slightly inferior to ADC12 in die casting and machining performance.

Magnesium alloy die-casting alloy

Magnesium alloys, noted for low density and high strength, are optimal for structural lightweighting in automotive, aerospace, and electronics.

Their high specific strength and damping qualities suit dynamic load applications well.
Yet, they exhibit lower corrosion resistance and reduced mechanical properties at high temperatures, key considerations in material selection.

  • AZ91D: This is a commonly used magnesium-aluminum alloy with medium strength, good casting properties, and corrosion resistance.
    AZ91D alloy is easy to process and is suitable for manufacturing various die-casting parts.
  • AM50A: This is a magnesium-silicon alloy that is known for its good ductility and high impact strength, making it suitable for die-cast parts that require a certain degree of resilience.
  • 1AS71: This is a magnesium-zinc alloy with high strength and hardness while maintaining good casting properties, making it suitable for manufacturing high-strength die-cast parts.
  • ZK60: This is a magnesium-zinc-copper alloy with very high strength and hardness, but relatively poor casting properties, making it suitable for manufacturing high-performance small die-cast parts.
  • WE54: This is a magnesium-rare earth alloy with excellent high-temperature performance and anti-creep ability,
    making it suitable for manufacturing die-casting parts for high-temperature working environments.

Zinc alloys die-casting 

Zinc alloys, with good casting properties and high strength, suit decorative and functional part fabrication. Copper alloys, renowned for superior electrical and thermal conductivity, excel in electrical and heat exchange applications. ty.

  • ZAMAK 2: This is a universal die-cast zinc alloy with good mechanical properties and surface finish, suitable for the manufacture of various complex shapes of parts,
    such as automotive parts, electrical housings, etc.
  • ZAMAK 3: As the most commonly used die-cast zinc alloy, ZAMAK 3 has excellent fluidity and corrosion resistance,
    which is suitable for the manufacture of demanding products, such as hardware accessories, household items, etc.
  • ZAMAK 5: Compared with ZAMAK 3, ZAMAK 5 has higher strength and toughness, which is suitable for the manufacturing of parts requiring greater loads,
    such as automotive parts, construction machinery parts, etc.
  • ZA-8: ZA-8 is a high-quality die-cast zinc alloy with excellent surface treatment properties and dimensional stability, often used in the manufacture of precision parts and decorative products.
  • AZ91D: This is an aluminum-containing zinc alloy that has good strength and heat resistance,
    and is commonly used in the manufacturing of parts in the automotive and aerospace industries.
  • ZA-27: ZA-27 is a kind of high aluminum zinc-based alloy, which overcomes the low-temperature brittleness of some alloys, has high strength and elongation,
    and is widely used in the manufacture of bearing bush, shaft sleeves, worm gear, etc.,
    mainly used in mining machinery, cement machinery, and other heavy machinery equipment.
  • Za-8: ZA-8 is the only hot chamber zinc die-cast alloy in the ZA series, with higher tensile strength, hardness, and creep properties,
    suitable for manufacturing parts in the automotive and aerospace industries, especially those requiring high density, high strength, and high durability.

Design Considerations in Die Casting

Die-casting design involves a complex process encompassing material selection, mold design, and optimization of process parameters.

Here are fundamental factors to consider during die-cast part design:

  • Material Properties: Choose appropriate die-casting alloys based on required mechanical properties, corrosion resistance, thermal conductivity, and electrical conductivity depending on the application.
  • Mold Design: Mold design must ensure precise dimensions and quality surfaces for the cast pieces.
    Consideration should include gating system layout, cooling system optimization, effective venting, and choice of parting lines.
  • Process Parameters: Temperatures, pressures, and speeds significantly impact the quality of the casting.
    Determine optimal process parameters through experimentation and simulation analysis.
  • Structural Optimization: Optimize the design of die-cast components to minimize uneven wall thicknesses,
    and internal defects such as porosity and shrinkage voids, and enhance overall strength.
  • Cost-effectiveness: Factor in costs including material, mold making, and production efficiency during the design phase.
  • Manufacturability: Ensure designs align with existing die-cast machine capabilities regarding clamping force, shot capacity, and cooling ability.
Die-cast technology
Die-cast technology

Latest Trends and Technologies in Design

  • Precision Die Casting: To meet high-performance demands, precision die casting techniques produce highly accurate and smooth-surfaced castings.
  • Computer-Aided Engineering (CAE): CAE technology’s role expands in identifying and solving potential issues early in the design stage, optimizing designs.
  • Smart Manufacturing: IoT sensors and data analytics monitor real-time casting processes and mold conditions, enhancing productivity and product quality.
  • Lightweight Designs: Industries like automotive and aerospace trend towards lighter die-cast components to decrease energy consumption and improve fuel efficiency.
  • Sustainable Materials: Growing environmental awareness pushes exploration into recyclable or biodegradable materials within the die-cast sector.

Key Points During Design

When designing, keep the following points in mind:

  • Avoid Sharp Corners and Complex Internal Structures: Such features can expedite mold wear and introduce production flaws.

Ensure Adequate Draft Angles: Facilitates easy removal of cast parts from molds.

  • Consider Shrinkage Rates: Account for shrinkage during cooling to avoid dimensional inconsistencies.
  • Tolerance Specifications: Select tolerances judiciously to ensure compatibility between die-cast components and other assemblies.

Conclusion

Die casting remains a critical manufacturing process that enables the mass production of high-quality, durable, and complex metal parts.

Its precision, speed, and efficiency make it the go-to solution for industries requiring high-volume production with consistent quality.

As manufacturing technologies continue to evolve, die casting will likely maintain its status as a cornerstone of industrial production.

Whether you’re looking to create lightweight aerospace components or intricate electronic housings,

die casting provides the ideal combination of precision and mass production capabilities.

Scroll to Top