4 Advice to Choose a structural foam molding

From the automotive industry and toy industry to the medical industry, a lot of businesses use injection molding to manufacture their products.

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If you’ve ever wondered about the different types of injection molding, you’re going to love this short guide.

We’ll explore all four of the main types of injection molding and tell you more about cost, design requirements, and functionality.

So, what are they?

Types Of Injection Molding

The main four types of injection molding are structural foam molding, external gas assist molding, internal gas assist molding, and insert molding (which is also known as overmolding). Each type of molding has different pros and cons.

1. Structural Foam Molding

In structural foam molding, the weight of a part that is made can be reduced by as much as 15%. Another benefit of structural foam molding is that because the injection pressures required are low, it’s possible to use aluminum instead of steel for this method.

Inert gas or alternatively a pelleted chemical blowing agent gets blended with thermoplastic resin inside the injection molding machine. The types of molds in injection molding via the structural foam molding method are usually aluminum but older or agnostic molds made of steel are fine too.

2. External Gas Assist Molding (EGA)

Inert gas is inserted into the mold for this method in order to help compensate for shrinkage. This type of resin or plastic injection molding is considered most suitable for thin-walled parts with a large surface area or detailed textured surfaces.

This is another lower pressure method but distinct from structural foam because it’s a little higher pressure and gives very crisp light results

3. Internal Gas Assist Molding

Resin and plastic injection molding parts for this type of molding are usually large, hollowed-out sections in thin-walled designs.

Parts are hollow allowing cavities to form by introducing inert gas into the mold after the resin has filled the cavity, creating a bubble of displacement.

4. Insert Molding or Overmolding

Insert molding or overmolding is the simplest and oldest style of molding. A piece is inserted and one material is molded around another material using a lot of pressure.

This can increase the strength of the part as well as its longevity making this the cheaper option. Therefore, the manufacturing process has fewer steps less time required.

Choosing Types Of Injection Molding

Still not sure which of these four types of injection molding is right for your requirements?

Learn more about what to look for in an injection molding company.

Nova Stevensville will discuss your project and establish the most cost-effective way to reach your project goals within budget.

Structural foam injection molding is a specialized process that allows for the production of large, lightweight, and durable plastic parts.

What sets it apart from traditional molding is the addition of a blowing agent or gas, which creates a cellular structure inside the part, reducing its overall weight while maintaining strength.

This unique process is ideal for applications where large, complex parts are needed without compromising quality.

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It’s widely used in industries like automotive, medical devices, and consumer goods, offering a cost-effective solution for producing parts that are strong, stable, and highly durable.

How Structural Foam Injection Molding Works

The structural foam injection molding process uses molten resin mixed with a blowing agent to create lightweight yet strong plastic parts.

This method involves several key steps, each contributing to the final product’s quality and durability.

Here’s how it works:

Step 1: Resin Injection with Blowing Agent

The process begins by injecting molten resin into a mold, which is then combined with a chemical blowing agent or nitrogen gas.

This blowing agent helps create gas bubbles inside the resin, preparing it for expansion within the mold.

Step 2: Foaming and Expansion

Once the resin enters the mold, the blowing agent activates, causing the resin to foam and expand.

This reaction forms a low-density cellular core within the part while maintaining a high-density outer skin.

The cellular structure reduces material use without sacrificing strength.

Step 3: Formation of the Solid Outer Skin

As the foaming resin fills the mold, the outermost layer solidifies upon contact with the mold walls.

This creates a strong, impact-resistant outer skin that enhances the part’s durability and aesthetic finish.

Step 4: Low-Pressure Molding for Efficiency

This process operates under lower pressure compared to traditional injection molding.

The lower pressure reduces wear and tear on the mold, allows for more complex and larger part designs, and shortens cycle times, making it both time- and cost-efficient.

Key Materials Used in Structural Foam Injection Molding

Various thermoplastics are used in structural foam injection molding, each chosen for its unique properties.

Here are some of the most common materials:

• Acrylonitrile Butadiene Styrene (ABS): Known for its toughness and impact resistance, ABS is ideal for parts requiring strength and durability, such as automotive components.
• Polypropylene (PP): PP is lightweight, flexible, and offers excellent chemical resistance, making it a popular choice for consumer goods and industrial applications.
• High-Density Polyethylene (HDPE): HDPE provides strength and weather resistance, making it suitable for outdoor equipment, like playgrounds and storage containers.
• Polycarbonate (PC): PC is valued for its high impact strength and clarity, often used for protective covers and medical devices.
• Nylon (PA): Offering high abrasion resistance and mechanical strength, Nylon is frequently chosen for applications needing durability under stress, such as gears and bearings.

Applications of Structural Foam Molding

Structural foam molding is widely used across various industries to produce large, complex parts that require a strong yet lightweight structure.

Here are some key applications:

• Automotive Parts: This process is ideal for vehicle components like roofs, door panels, and other structural parts that need to be both strong and lightweight, improving fuel efficiency and performance.
• Medical Equipment: Large diagnostic devices and covers benefit from structural foam molding due to its ability to produce durable, rigid housings that protect sensitive equipment.
• Consumer Goods: Furniture frames, sports equipment, and household appliances are often made using structural foam molding, as the process allows for complex designs with high strength-to-weight ratios.

Advantages and Disadvantages of Structural Foam Injection Molding

Advantages

Structural foam injection molding offers several benefits that make it a preferred process for creating large, complex parts:

• Lightweight but Strong: The foamed core reduces material use while maintaining strength, making parts both lightweight and robust.
• Reduced Cost: With less resin and lower clamping pressures, tooling and energy costs are significantly lower than traditional methods.
• Design Flexibility: Structural foam allows for thicker walls, complex geometries, and larger parts that traditional molding cannot easily accommodate.
• Improved Dimensional Stability: This process reduces warpage and shrinkage, ensuring precision and stability for large, intricate parts.
• Environmental Benefits: The process uses fewer materials and less energy, contributing to a lower environmental impact.

Disadvantages

While structural foam molding offers many advantages, it does have some limitations:

• Higher Initial Costs: The specialized equipment and molds can be expensive to set up.
• Surface Finish: Aesthetic parts may need secondary processes like sanding or painting to improve their appearance.

Structural Foam vs. Traditional Injection Molding