PPS injection molding

6. Tooling Design for PPS Moulding

Premium Mold Materials:

• Cavity/Core: Tool steels H13, S7, or stainless steels

• Hardness: 48-52 HRC minimum

• Corrosion Resistance: Essential for consistent performance

• Surface Treatments: Nitriding, chrome plating, or PVD coatings

• Thermal Conductivity: High conductivity materials preferred

Runner System Design:

• Full Round Runners: 6-10mm diameter minimum

• Runner Balancing: Critical for multi-cavity molds

• Hot Runner Systems: Externally heated with precise control

• Gate Types:

  • Edge Gates: Most common, easy to trim

  • Direct Sprue: For single-cavity molds

  • Submarine Gates: For automatic degating

  • Valve Gates: For sequential filling

Temperature Control System:

• High-Temperature Capability: Up to 160°C operation

• Conformal Cooling: Follows part contours closely

• Multiple Circuits: Separate control for different zones

• Temperature Uniformity: ±3°C across mold surface

• Insulation: Between mold halves to maintain temperature

Venting System:

• Vent Depth: 0.015-0.025mm

• Vent Width: 6-10mm

• Strategic Placement: All end-of-fill areas

• Importance: Prevents burning and incomplete filling

• Maintenance: Regular cleaning essential

Ejection System:

• Ejector Pins: Larger diameter to reduce surface pressure

• Material Selection: High-temperature resistant steels

• Surface Finish: Highly polished to prevent sticking

• Ejection Force: Higher due to high stiffness

• Stripper Plates: For thin-walled parts

Surface Finish Requirements:

• Polish Levels: SPI B-1 to C-3 typically

• Texture Options: Limited due to high stiffness

• Draft Angles: 1-2° minimum, more for textured surfaces

• Maintenance: Regular polishing to maintain quality

7. Crystallinity Control in PPS Processing

Understanding PPS Crystallinity:

• Maximum Crystallinity: Up to 65% achievable

• Crystallization Temperature: 120-140°C (248-284°F)

• Crystal Structure: Complex orthorhombic system

• Property Relationship: Direct correlation with mechanical properties

Factors Affecting Crystallinity:

Processing for Optimal Crystallinity:

1. Mold Temperature: Maintain 130-160°C for adequate crystallization

2. Holding Pressure: Sufficient to pack during crystallization

3. Cooling Rate: Controlled to allow proper crystal growth

4. Post-Mould Annealing: Optional for maximum properties

Annealing Processes:

• Purpose: Increase crystallinity, relieve stresses, improve properties

• Temperature: 200-220°C (392-428°F) for 2-4 hours

• Atmosphere: Air or inert gas

• Benefits: Increased HDT, improved chemical resistance

• Applications: For maximum performance requirements

Crystallinity Measurement:

• DSC Analysis: Most common method

• XRD: For crystal structure analysis

• Density Methods: Indirect measurement

• FTIR Spectroscopy: For chemical analysis

8. Part Design Guidelines for PPS Components

Wall Thickness Principles:

• General Range: 1.0-4.0mm

• Optimal Thickness: 1.5-2.5mm

• Uniformity: Critical (maximum 25% variation)

• Minimum Thickness: 0.5mm possible with optimized processing

• Thick Sections: Core out to minimize sink marks

Radii and Corner Design:

• Internal Radii: Minimum 0.5 times wall thickness

• External Radii: Internal radius plus wall thickness

• Stress Concentration: Avoid sharp corners completely

• Transition Design: Gradual changes (3:1 maximum ratio)

Rib and Boss Design:

• Rib Thickness: 40-50% of adjacent wall

• Rib Height: Maximum 2.5 times wall thickness

• Boss Design: Must be cored and connected with ribs

• Draft Angles: 1-2° per side minimum

• Fillet Radii: Generous at base connections

Draft Angle Requirements:

• Standard Applications: 1-2° per side

• High-Aspect Features: Additional draft may be required

• Textured Surfaces: Add 1° per 0.025mm texture depth

• Deep Draw Parts: Additional draft for ejection

Tolerance Considerations:

• Standard Tolerances: ±0.1% or ±0.1mm, whichever is greater

• Critical Dimensions: ±0.05% achievable with optimization

• Thermal Expansion: Account for 4.9 x 10^-5 /°C (flow direction)

• Anisotropic Shrinkage: Different in flow vs. cross-flow directions

Assembly Feature Design:

• Snap-fits: Limited use due to high stiffness and brittleness

• Threads: Molded-in possible with proper design

• Press-fits: Careful interference calculations required

• Ultrasonic Welding: Possible but requires optimization

• Mechanical Fastening: Most common assembly method

9. Quality Control and Testing Protocols

Material Qualification Testing:

Thermal Analysis:

• DSC Analysis: Melting point (285°C), crystallinity percentage

• TGA: Thermal stability, decomposition temperature

• DMA: Dynamic mechanical properties at temperature

• HDT/Vicat: Heat deflection and softening points

Mechanical Testing:

• Tensile Properties: ASTM D638 at room and elevated temperatures

• Flexural Testing: ASTM D790 for stiffness verification

• Impact Resistance: ASTM D256 (Izod/Charpy)

• Compressive Strength: ASTM D695 for structural validation

Electrical Properties:

• Dielectric Strength: ASTM D149

• CTI Testing: ASTM D3638 for tracking resistance

• Volume Resistivity: ASTM D257

• Arc Resistance: ASTM D495

Chemical and Environmental:

• Chemical Resistance: Immersion testing per ASTM D543

• Hydrolytic Stability: For automotive and industrial applications

• Weathering Tests: QUV, xenon arc for outdoor applications

• Aging Studies: Long-term property retention at temperature

Process Control Parameters:

• Melt Temperature: Continuous monitoring with pyrometers

• Pressure Profiles: Injection and holding phase documentation

• Cushion Consistency: ±0.3mm variation maximum

• Cycle Time: Statistical process control implementation

Part Validation Testing:

• Dimensional Verification: CMM with thermal compensation

• Surface Quality: Inspection per application requirements

• Non-destructive Testing: For critical applications

• Functional Testing: Under simulated service conditions

Certification and Documentation:

• Material Traceability: Full lot tracking

• Process Documentation: Complete parameter records

• Quality Certifications: IATF 16949, AS9100, ISO 13485

• Industry-Specific Requirements: Automotive, aerospace, medical

10. Industry Applications and Case Studies

Automotive Applications:

• Underhood Components: Throttle bodies, sensors, connectors

• Fuel System Parts: Pump components, fuel rails

• Electrical Systems: Connectors, sockets, housings

• Lighting: Reflectors, LED housings

• Benefits: Weight reduction, chemical resistance, high temperature capability

Electrical and Electronics:

• Connectors: SMT, through-hole, board-to-board

• Switchgear: Housings, insulating components

• Motor Parts: Brush holders, end caps, commutators

• Semiconductor: Wafer carriers, handling components

• Benefits: Flame retardancy, dimensional stability, high CTI

Industrial Equipment:

• Pump Components: Impellers, housings, wear rings

• Valve Parts: Seats, balls, stems, housings

• Compressor Components: Vanes, seals, shrouds

• Chemical Processing: Equipment for aggressive environments

• Benefits: Chemical resistance, wear resistance, high temperature

Aerospace and Defense:

• Interior Components: Brackets, clips, fasteners

• Engine Components: Seals, bushings, sensor housings

• Electrical Systems: Connectors, insulating components

• Benefits: Light weight, flame/smoke/toxicity compliance, high temperature

Consumer Products:

• Appliance Components: Heating elements, housings

• Cookware: Handles, knobs, components

• Lighting: Reflectors, sockets

• Benefits: High temperature resistance, durability

Emerging Applications:

• Electric Vehicles: High-voltage connectors, battery components

• Renewable Energy: Solar, wind power components

• Medical Equipment: Sterilizable components

• Additive Manufacturing: For complex geometries