How to Choose the Right Nylon: A Systematic Material Selection Guide
Selecting the correct nylon grade is one of the most consequential decisions in engineering plastics procurement. A wrong choice — choosing PA66 where PA6 suffices, or specifying unfilled nylon for a structural application — can result in field failures, production delays, and costly material substitutions mid-project.
This guide provides a structured decision framework based on actual engineering criteria: mechanical requirements, thermal environment, moisture exposure, chemical contact, regulatory compliance, and cost. Every selection factor is tied to real-world data so you can make evidence-based decisions, not rely on generic rule-of-thumb guidance.
The Five Critical Selection Criteria
Before examining specific grades, establish the priority order of these five criteria for your application. Most applications fail because two or more criteria conflict — understanding which takes precedence avoids costly design changes later.
| Criterion | Why It Matters | Primary Impact | Secondary Impact |
|---|---|---|---|
| Mechanical Strength | Load-bearing capacity required | Structural parts, brackets | Gear teeth, bearing surfaces |
| Thermal Resistance | Maximum service temperature | Engine components, high-heat zones | Processing window |
| Moisture Sensitivity | Operating humidity environment | Dimensional stability | Electrical properties |
| Chemical Exposure | Fluids in contact with part | Fuel, oil, acid, alkali | Cleaning agents, solvents |
| Regulatory Compliance | Market and industry standards | Food, medical, potable water | Automotive, aerospace |
PA6 vs. PA66: The Fundamental Choice
PA6 and PA66 together account for over 90% of global nylon consumption. Understanding their differences is the foundation of all material selection decisions.
| Propriété | PA6 | PA66 | Winner |
|---|---|---|---|
| Point de fusion | 220-225°C | 260-265°C | PA66 |
| Crystallinity | Lower (~40%) | Higher (~50%) | PA66 for dimensional stability |
| Résistance à la traction | 70-85 MPa | 80-90 MPa | PA66 |
| Résistance aux chocs | Higher (tougher) | Lower (stiffer) | PA6 |
| Rétrécissement du moule | 1.0-1.5% | 1.3-1.8% | PA6 (lower warpage) |
| Water Absorption | 8.5-9.0% | 8.0-8.5% | Similar |
| Processing Temperature | 230-260°C | 270-295°C | PA6 (lower energy) |
| Cost | Plus bas | Plus élevé | PA6 (20-30% cheaper) |
| Fatigue Resistance | Good | Excellent | PA66 |
Reinforced Grades: When to Specify Glass or Carbon Fiber
Unreinforced nylon serves many applications well, but structural, high-temperature, and high-precision applications almost always require reinforcement. GF30 and GF33 (glass fiber) are the workhorses; CF30 (carbon fiber) is selected for ultra-lightweight or high-stiffness applications.
| Grade | Résistance à la traction | Module de flexion | HDT (1.82 MPa) | Avantage clé | Applications typiques |
|---|---|---|---|---|---|
| PA6 (unfilled) | 70-85 MPa | 2,800 MPa | 70°C | Tough, cost-effective | Gears, bushes, flexible parts |
| PA66 (unfilled) | 80-90 MPa | 3,000 MPa | 80°C | Stiff, fatigue-resistant | Structural parts, bearings |
| PA6-GF30 | 160-180 MPa | 8,500 MPa | 215°C | Heat resistant, stiff | Engine covers, brackets |
| PA66-GF33 | 190-210 MPa | 10,500 MPa | 250°C | Highest stiffness | Structural automotive |
| PA6-GF50 | 200-230 MPa | 15,000 MPa | 220°C | Metal replacement | Heavy-load brackets |
| PA66-CF30 | 240-280 MPa | 20,000 MPa | 260°C | Lightweight, ESD-safe | Robotics, aerospace |
| PA12 (unfilled) | 45-55 MPa | 1,800 MPa | 85°C | Low moisture, flexible | Fluid systems, catheters |
Moisture and Environment: Matching to Operating Conditions
Moisture absorption is the most misjudged selection factor. Engineers often underestimate how dramatically water plasticizes nylon, reducing modulus by 40% and increasing dimensions significantly.
| Operating Environment | Recommended Grade | Why | Alternative |
|---|---|---|---|
| Dry interior (<50% RH) | PA66 | Dimensional accuracy, stiffness | PA6 |
| Humid interior (50-80% RH) | PA66-GF30 | Moisture-stable when reinforced | PA6-GF30 |
| Outdoor exposed | PA66-GF30 + UV | UV stabilization essential | PA12 |
| Under-hood automotive | PA66-HT or PA66-GF30 | Heat-stabilized for >150°C | PA6-GF30 |
| Potable water contact | PA66-GF30 or PA12 | NSF/ANSI 61 compliant grades | PA66 approved |
| Chemical plant | PA66 or PVDF | Acid/alkali resistant grades | PP or HDPE |
| Low temperature (-30°C) | PA66 | Retains toughness at low temps | PA66-GF30 |
| High temperature (>200°C) | PA66-GF30 or PPA | Beyond PA66 capacity | PEEK or PPS |
Application-Specific Selection Matrix
Rather than selecting by property alone, match the material to the application category for the fastest path to the right grade.
| Application Category | L'industrie | Recommended Nylon | Certification Needed |
|---|---|---|---|
| Air intake manifolds | Automobile | PA66-GF30 + heat stabilizer | OEM approval, under-hood thermal |
| Fuel rails and lines | Automobile | PA66-GF30 or PA12 | EN 594, SAE emissions |
| Electrical connectors | E&E, Automotive | PA66 V-0, PA6 V-2 | UL 94, IEC 60335 |
| Beverage tubing and fittings | Food & Beverage | PA12, PA66 food-grade | FDA 21 CFR 177.1500, EU 10/2011 |
| Medical device housings | Médical | PA66 medical-grade | ISO 10993, FDA 510(k) |
| Industrial gears and bearings | Machinery | PA66-GF30 or PA66-CF30 | None mandatory |
| Sports equipment | Consumer | PA6, PA66 | REACH, CPSIA for toys |
| Drone structural frames | Robotics/Aero | PA66-CF30 | UL 94 V-0 if electrical |
FAQs
Q1: We are moving from aluminum to nylon for an automotive bracket. Which grade do we start with?
A: Begin with PA66-GF33 (33% glass fiber reinforced PA66) as your baseline. It provides tensile strength similar to die-cast aluminum (~190 MPa) with a stiffness of approximately 10,000 MPa. Use FEA simulation with orthotropic material properties (flow direction vs. cross-flow shrinkage differ significantly in reinforced nylon) and apply a minimum 2.5x safety factor on ultimate tensile strength.
Q2: When should I choose PA12 over PA6 or PA66?
A: PA12 is your choice when: (1) parts operate in constant moisture or outdoor environments where dimensional stability matters (PA12 swells only 1.5% vs. 9% for PA6), (2) you need chemical resistance to polar solvents, brake fluids, or salt solutions, or (3) you require flexibility with good mechanical properties (catheters, fuel lines, pneumatic tubing). Accept PA12’s lower strength and higher cost as the trade-off for its superior moisture and chemical performance.
Q3: Can I use recycled nylon, and how does it compare to virgin material?
A: Post-industrial recycled (PIR) nylon from reground runners and sprues performs nearly identically to virgin when properly classified and compounded. Post-consumer recycled (PCR) nylon has more variable properties. Always request the technical data sheet for the specific recycled grade, not a generic virgin comparison. For food contact or medical applications, virgin is typically required for full regulatory compliance.
Q4: We need a heat-resistant grade above 200°C. What options exist beyond standard nylon?
A: For applications above 200°C continuous service temperature, standard PA66-GF30 reaches its practical limit at approximately 230°C HDT. Consider PPA (polyphthalamide, e.g., Amodel) for 230-280°C service, PPS (polyphenylene sulfide) for 240°C+ with excellent chemical resistance, or PEEK for 250°C+ applications. These high-temperature polymers cost 5-15x more than PA66 but provide the thermal performance needed for under-hood hybrids and EV power electronics cooling systems.
