Solving Overmolding & Insert Displacement Pain Points for EV Fasteners


Posted July 7, 2026 by cnmoulding

Overmolded fasteners, structural brackets, and insulated busbar tighteners are backbone components in NEV battery packs and chassis assemblies.

 
Overmolded fasteners, structural brackets, and insulated busbar tighteners are backbone components in NEV battery packs and chassis assemblies. Insert molding—the process of encapsulating metal fasteners within high-performance engineering plastics (such as PBT-GF30 or PPS)—offers excellent weight savings and electrical insulation.

However, joining two vastly different materials (metal and plastic) creates unique manufacturing headaches. Below is how we solve the top 3 failure modes in automotive insert molding.

1. Process Pain Point: Insert Displacement and Mold Crushing
The Problem: During the high-pressure packing stage of the injection molding cycle, molten plastic rushes into the cavity at pressures exceeding $100\text{ MPa}$. If the metal insert (e.g., a brass threaded bushing or steel bolt) is not rigidly secured, this immense pressure will shift or tilt it. Even a $0.1\text{ mm}$ displacement results in an out-of-tolerance automotive part. Worse, if an insert is misaligned, the closing action of the injection mold can crush the steel core, causing catastrophic tooling damage.

Our Solution:
We design custom, high-precision seating pockets with mechanical locking pins within the injection mold to mechanically clamp the metal insert. For high-volume BYD-tier projects, we integrate automated robotic arms equipped with optical positioning sensors. The automation ensures the insert is seated perfectly within $\pm0.02\text{ mm}$ before the mold clamping sequence initiates, completely eliminating mold-crushing risks.

2. Material Pain Point: Thermal Expansion Mismatch & Micro-Cracking
The Problem: Metals and plastics have vastly different Coefficients of Thermal Expansion (CTE). When the hot plastic shell ($260^\circ\text{C}+$) shrinks around a cold metal insert inside the mold, intense internal residual stresses are locked into the plastic. Over time, or during thermal cycling tests (from $-40^\circ\text{C}$ to $120^\circ\text{C}$), these internal stresses release, causing the plastic housing to develop micro-cracks and fail.

Our Solution:
To mitigate CTE mismatch, we implement a strict insert pre-heating process ($100^\circ\text{C}-130^\circ\text{C}$) before loading them into the mold. This reduces the thermal shock between the substrate and the melt. Furthermore, we optimize the injection molding parameters by employing a gradual cooling curve and prolonged holding pressures, allowing the plastic molecules to relax and dramatically minimizing molded-in residual stress.

3. Tooling Pain Point: Achieving Airtight Metal-Plastic Bonding
The Problem: Plastics do not naturally bond to smooth metal surfaces. Without a proper mechanical or chemical interface, moisture and environmental contaminants will penetrate the metal-plastic boundary, causing corrosion or electrical short-circuits in high-voltage EV environments.

Our Solution:
We work closely with clients during the early DFM stage to implement knurling, grooves, or undercuts onto the metal insert design, creating a robust mechanical interlock. Inside the tool, we utilize a perfectly balanced hot runner system to ensure the plastic melt encapsulates the knurled metal interface at peak temperature and uniform pressure, achieving an airtight, high-integrity structural bond that passes strict automotive pull-out and torque testing.

Looking for a reliable IATF 16949 certified toolmaker in China for your next NEV project? Contact our Shanghai engineering team today at [Your Email] for a free DFM analysis within 48 hours
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Contact Email [email protected]
Issued By CNMOULDING
Phone 0086-021-52913487
Country China
Categories Automotive , Industry , Manufacturing
Tags overmolding , plastic injection molding
Last Updated July 7, 2026