The substrates in over-molding often include materials like PA, PC, ABS/PC, and ABS, while TPE, TPU, TPR, and TPO are common choices for the overmolding layer. This blend of soft and hard plastics represents the most typical form of overmolding.

Commonly, the substrate in overmolding is a hard plastic like PA or PC. The overmolded material, however, can be a flexible plastic such as TPE or TPU, or even another hard material.

2-shot molding combines both substrate molding and overmolding in a single injection molding machine. Here, after the substrate is molded, it’s rotated to another station within the same machine for overmolding, eliminating the need to manually transfer the substrate.

Poor Adhesion: This issue often arises due to incompatibility between materials. For different materials, compatible overmolding materials must be selected. Additionally, a low temperature of the substrate’s surface can lead to poor adhesion. On the other hand, excessively strong adhesion can create recycling challenges for the product.

Although insert molding and 2-shot molding fall under overmolding, they are often referred to separately. In a narrower definition, overmolding specifically involves a plastic substrate manually placed into the mold.

However, 2-shot molding requires highly precise molds and thus involves greater initial investment costs. Therefore, the choice between these methods depends on the production volume:

Short Shot: Even a slight inadequacy in the injection can cause aesthetic defects, leading to product rejection. It’s crucial to design the gate location thoughtfully to prevent short shots. A Design for Manufacturability (DFM) assessment can be used to evaluate the suitability of gate placement, focusing mainly on the required injection pressure.

Insert molding typically involves inserting pre-fabricated parts, often made of metals like copper or stainless steel, into an injection mold. These parts can also be made from other materials such as glass, wood, or fiber.

Precision Fit Between Substrate and Mold: The fit between the substrate and the mold cavity in overmolding needs to be very precise. The gap between the substrate and the mold cavity after inserting the substrate should be between 0.01 to 0.03mm. This precision is crucial because materials like TPE, known for their fluidity, can easily cause flash if the gap is too large.

Additionally, in scenarios where the maximum thickness of an injection-molded product is exceeded, a two-shot injection molding process may be used. This approach ensures each individual molding stays within the maximum allowable thickness.

Overmolding usually involves a single overlay, requiring two injection molds. The final product is a combination of two materials or two color variations of the same material.

From this distinction, it’s evident that insert molding usually requires just one injection mold, whereas overmolding necessitates at least two, and occasionally three, molds.

Creating molds for overmolding requires higher precision and a thorough understanding of the overmolding materials. The following are essential aspects to consider in overmolding mold design:

This makes 2-shot molding more efficient and labor-saving. Additionally, since the substrate remains hot during overmolding in 2-shot processes, it often results in a stronger bond between the substrate and overmolding material.

Overmolding is a widely used plastic molding process with many advantages but also some limitations. Here are the main pros and cons of overmolding:

To mitigate adhesion issues, it’s common to design holes or grooves at the edges of the overmolded area. These features, being larger internally, help to lock the overmold in place and reduce the reliance on adhesive strength, making it easier for the overmold to bond with the substrate.

Overmolding is a process where a substrate, typically a pre-formed plastic part, is placed inside a mold. During the process, molten plastic is injected into the mold cavity, enveloping the substrate in the empty areas. Once cooled, the two materials fuse into a single product.

Conversely, a gap that is too small or negative, such as -0.01 to -0.02mm, can create indentations on the substrate surface. Therefore, the mold must be manufactured with high accuracy.

Overmolding, also called plastic overmolding, molding over molding, or injection overmolding,  is a crucial injection molding technique widely used in everyday items like toothbrushes, power tool housings, and car light panels. This article will explain overmolding, highlighting its common challenges and essential precautions.

In traditional overmolding, the substrate is first injection molded, removed from the mold, and then manually placed into another mold for overmolding.

Flash: Excessive gaps between the mold cavity and the substrate can lead to flash (excess plastic). Moreover, if the gate design is improper, leading to excessive injection pressure (to avoid short shots), it can also result in flash.

Theoretically, the possibilities extend beyond these mentioned materials. Essentially, any plastic can be used for over-molding. For specific requirements, please feel free to contact us for more information.

Gate Design in Overmolding: The design of the gates in overmolding molds is highly critical. They must ensure complete filling while maintaining sufficient adhesive force. The key is to ensure that all areas to be overmolded are not too far from the gates. This is to avoid insufficient injection pressure or too low temperatures in those areas, which could affect the quality of the over molding.

Understanding the nuances between overmolding, insert molding, and 2-shot molding is crucial for selecting the right process for specific applications, balancing efficiency, cost, and production volume.

In summary, while overmolding technology offers enhanced functionality and aesthetics, it also brings challenges in cost, design, and material selection.

In conclusion, overmolding is a versatile and widely used plastic molding technique that enhances product functionality and aesthetics. Despite its complexity, with proper material selection, precise mold design, and attention to key issues like adhesion, short shots, and flash, overmolding offers significant benefits.

It’s also possible to use hard plastics for both the substrate and the overmold, usually the same material, often employed in multi-color combinations for aesthetic appeal.

It’s crucial that the overmolding material has a melting point equal to or lower than the substrate’s. Using the same material for both is possible, but it requires careful adjustment of the injection molding temperature to prevent the substrate from partially melting.

While theoretically, overmolding can be repeated multiple times, such practices are rare in real-world applications and are not the focus of this discussion.

There are instances of double overmolding as well, which necessitates three molds, resulting in a product composed of three materials or color variations.