Essential Precautions for High-Quality Plastic Injection Molded Parts

Plastic injection molding is a widely used manufacturing process, but producing high-quality parts requires attention to every detail. From material selection to post-processing, each step has its own precautions that directly affect the final product’s performance, apparence, et coûter. This article will break down the key precautions for each stage of plastic injection molded parts production to help you avoid common pitfalls and improve product quality.

Table des matières

1. Précautions de sélection des matériaux

Choosing the right material is the foundation of making excellent plastic injection molded parts. The material must match the part’s intended use, performance requirements, and cost budget. Here’s a detailed breakdown of the key factors to consider:

Facteur clé	Description	Pourquoi ça compte
Resin type	Different resins (Par exemple, Pp, Abs, PC) have unique characteristics. PP is lightweight and chemical-resistant; ABS has good impact strength; PC is transparent and heat-resistant.	Using the wrong resin type can make the part unable to meet basic performance needs. Par exemple, using PP for a part that needs high transparency will fail.
Thermal properties	Include melting point, Température de déviation de la chaleur, et stabilité thermique.	It determines if the material can withstand the injection molding process temperature and the part’s working environment temperature. Poor thermal stability leads to material degradation during molding.
Propriétés mécaniques	Cover tensile strength, force d'impact, dureté, et la flexibilité.	Relate to the part’s ability to resist external forces. A part used in a high-impact scenario needs good impact strength; sinon, it will break easily.
Résistance chimique	The material’s ability to resist corrosion from chemicals like oils, solvants, et les acides.	Critical for parts used in chemical-related fields. Par exemple, a fuel tank part must be resistant to fuel corrosion.
Moisture absorption	Quelques matériaux (Par exemple, nylon) absorb moisture easily.	Moisture in the material causes bubbles and defects in the molded part. Donc, materials with high moisture absorption need pre-drying.
Recycled content	The proportion of recycled plastic in the material.	Affects cost and environmental friendliness, but too much recycled content may reduce material performance.
Rentabilité	Balance between material performance and cost.	High-performance materials are often expensive. Pour les pièces non critiques, choosing a cost-effective material can reduce production costs.

2. Considérations de conception

A reasonable part design not only simplifies the injection molding process but also improves the part’s quality and reduces defects. Here are the key design precautions:

Wall thickness uniformity: Uneven wall thickness causes uneven cooling and shrinkage, leading to warpage and sink marks. Keep the wall thickness as uniform as possible. If thickness variation is necessary, utiliser des transitions progressives (Par exemple, rétroviser) instead of sudden changes.
Angles de projet: Ajouter des angles de projet (généralement 1-5 degrés) to the part’s vertical surfaces. This helps the part eject smoothly from the mold and prevents scratches on the part surface. Sans angles de projet, the part may get stuck in the mold.
Rib design: Ribs are used to enhance the part’s stiffness without increasing wall thickness. The height of the rib should not exceed 3 times the wall thickness, and the width should be 0.5-0.7 times the wall thickness. Aussi, add fillets at the rib’s root to avoid stress concentration.
Bosses and supports: Bosses are used for assembly (Par exemple, trous à vis). The diameter of the boss should be 2-3 times the diameter of the screw, and the height should not exceed 2 times the diameter. Add supporting ribs around the boss to prevent it from breaking.
Undercuts and side actions: Sous-dépouille (Par exemple, grooves on the side of the part) make the part hard to eject. Si des sous-dépréciations sont nécessaires, use side actions or slides in the mold. But this increases mold complexity and cost, so minimize undercuts when possible.
Parting lines: The parting line is where the two halves of the mold meet. Design the parting line to be easy to process and remove flash. Avoid placing the parting line on the visible surface of the part to improve appearance.
Gate and runner design: The gate is the channel through which the molten plastic enters the mold cavity. Choose the right gate type (Par exemple, edge gate, sprue gate) et taille. The runner should be designed to ensure uniform flow of molten plastic to each cavity. Shorten the runner length to reduce material waste.

3. Mold Maintenance and Inspection

The mold is the core tool of injection molding, and its condition directly affects the part’s quality and production efficiency. Regular maintenance and inspection are essential:

Routine Maintenance Tasks

Mold cleaning: Clean the mold cavity, coureur, and vent every 8-12 heures de production. Use a soft cloth or brush to remove plastic residues and dirt. Avoid using hard tools that may scratch the mold surface.
Corrosion prevention: Apply anti-rust oil to the mold surface when it’s not in use for a long time. For molds used in humid environments, use corrosion-resistant materials (Par exemple, acier inoxydable) for key components.
Venting check: Check the mold vents regularly. Clogged vents cause air trapping in the mold cavity, leading to bubbles and incomplete filling. Clean the vents with a small drill or needle if necessary.
Ejector pin maintenance: Lubricate the ejector pins every day to ensure smooth movement. Check for wear and bending of the ejector pins. Replace worn or bent pins in time to avoid damaging the part or the mold.

Periodic Inspection Items

Inspection Item	Inspection Frequency	Méthode d'inspection
Cooling system checks	Every month	Check if the cooling water channels are blocked. Use a pressure tester to test the water pressure. Ensure uniform cooling of the mold.
Mold alignment	Chaque 3 mois	Use a dial indicator to measure the parallelism and perpendicularity of the mold halves. Adjust the mold clamping force if there’s misalignment.
Wear and tear assessment	Chaque 6 mois	Inspecter la cavité du moule, cœur, and other key components for wear. Measure the dimensions of the mold parts and compare them with the original design. Replace severely worn parts.

4. Processing Parameters

Proper setting of processing parameters is crucial for obtaining high-quality parts. Even small deviations in parameters can cause defects. Here’s a guide to the key processing parameters:

Key Parameters and Their Effects

Paramètre	Plage optimale (Example for ABS)	Effect of Too High	Effect of Too Low
Vitesse d'injection	50-80 mm / s	Causes jetting (irregular flow marks) and flash.	Leads to incomplete filling of the mold cavity.
Pression d'injection	80-120 MPA	Results in excessive stress in the part, causing warpage and cracking.	Can’t fill the mold completely, especially for thin-walled parts.
Melt temperature	220-250 ° C	Degrades the plastic, producing black spots and poor mechanical properties.	The plastic is not fully melted, leading to uneven flow and cold joints.
Temps de refroidissement	15-30 s	Increases production cycle time and reduces efficiency.	The part is not fully cooled, causing deformation when ejected.
Cycle time optimization	Balance of filling, refroidissement, and ejection time	Over-optimization (too short) leads to defects; under-optimization (too long) increases cost.	–
Drying conditions	Pour le nylon: 80-100 ° C, 4-6 heures	Over-drying makes the material brittle.	Insufficient drying causes bubbles in the part.
Screw speed	80-120 RPM	High speed generates too much heat, degrading the material.	Low speed leads to incomplete plastic melting and mixing.

A common question: How to adjust processing parameters when facing warpage? D'abord, check if the cooling time is sufficient. Sinon, extend it. Alors, reduce the injection pressure and melt temperature to reduce internal stress. Aussi, ensure uniform wall thickness in the part design.

5. Contrôle et test de qualité

Quality control and testing throughout the production process ensure that only qualified parts leave the factory. Voici le processus clé:

Testing Items and Methods

Précision dimensionnelle: Utiliser des étriers, micromètres, et coordonner les machines de mesure (Cmm) to measure the part’s key dimensions. Compare the measured values with the design tolerances. Sampling frequency: 5 parts per hour for initial production, 2 parts per hour for stable production.
Finition de surface: Inspect the part surface with the naked eye and a magnifying glass (10x). Check for defects like scratches, bulles, éclair, and sink marks. Reject parts with obvious surface defects.
Warpage and shrinkage: Place the part on a flat surface to check warpage. Use a feeler gauge to measure the gap. For shrinkage, measure the part’s dimensions and calculate the shrinkage rate (compared to the mold size). The acceptable shrinkage rate varies by material (Par exemple, Pp: 1.5-2.5%, Abs: 0.5-0.8%).
Flash and burrs: Check the part’s edges and parting lines for flash and burrs. Use a deburring tool to remove small burrs; reject parts with large flash.
Material flow analysis: Use simulation software (Par exemple, Flux de moulage) to analyze the molten plastic flow in the mold cavity before production. Identify potential problems like short shots and uneven flow, and adjust the mold or processing parameters accordingly.
Tests non destructeurs: Pour les pièces critiques (Par exemple, automotive and medical parts), use ultrasonic testing and X-ray testing to check for internal defects like voids and delamination.

6. Post-traitement et finition

Post-processing improves the part’s appearance, performance, and assembly ability. Here are the key precautions:

Débarquant: Use manual deburring (fichiers, papier de verre), mechanical deburring (rotary brushes), or ultrasonic deburring. Pour les pièces de précision, avoid excessive force during deburring to prevent deformation.
Peinture et revêtement: Clean the part surface thoroughly before painting to remove oil and dust. Choose the right paint (Par exemple, acrylic paint for good adhesion, enamel paint for durability). Control the paint thickness (15-30 µm) to avoid drips and uneven coating.
Assembly considerations: Ensure the part’s assembly features (Par exemple, les patrons, trous) meet the assembly requirements. Check the fit between parts; avoid over-tight or over-loose fits. Use appropriate assembly tools to prevent damaging the parts.
Traitement thermique: Quelques matériaux (Par exemple, nylon) need heat treatment (recuit) Pour réduire le stress interne. Annealing conditions: Chauffer la pièce à 80-100 ° C, s'occuper de 1-2 heures, Puis refroidir lentement. This prevents warpage and cracking during use.
Soudage à ultrasons: Used to join two plastic parts. Control the welding time (0.5-2 s) et la pression (10-30 N) to ensure a strong weld without damaging the parts. The weld strength should be at least 80% of the base material strength.
Laser marking: Used for marking logos, numéros de série, and other information. Adjust the laser power (10-30 W) et la vitesse (50-100 mm / s) to get clear and durable marks. Avoid marking on the part’s stress concentration areas.
Traitement de surface: For parts needing better wear resistance or aesthetics, use surface treatments like electroplating (for metal-like appearance) et a tiré un coup de pied (for improved surface hardness). Choose the right treatment method based on the material and requirements.

La vue de la technologie Yigu

À la technologie Yigu, we believe that high-quality plastic injection molded parts come from strict control of every production link. Material selection should balance performance and cost; design should be mold-friendly; mold maintenance ensures stable production; processing parameters need precise adjustment; quality testing guarantees product reliability; post-processing enhances added value. We integrate these precautions into our production process, using advanced simulation tools and testing equipment to provide customers with high-quality parts.

FAQ

Q: What should I do if the plastic injection molded part has bubbles?

UN: D'abord, check if the material is fully dried (especially for moisture-absorbing materials). Alors, inspect the mold vents for clogging and clean them if needed. Aussi, reduce the melt temperature and increase the injection speed slightly to avoid air trapping.

Q: How to prevent warpage of plastic injection molded parts?

UN: Ensure uniform wall thickness in the part design. Extend the cooling time to make the part cool evenly. Reduce the injection pressure and melt temperature to reduce internal stress. Aussi, check the mold alignment and adjust if necessary.

Q: What factors affect the cost of plastic injection molded parts?

UN: Key factors include material cost (resin type and recycled content), Coût de la moisissure (complexity and material), processing cost (cycle time and energy consumption), and post-processing cost (peinture, soudage, etc.). Optimizing design (reducing undercuts) and processing parameters (shortening cycle time) can reduce costs.