Nylon Chemical Resistance: Acids, Bases, Solvents, Automotive Fluids, and Food Contact
Chemical resistance is the single most misunderstood property of nylon in engineering procurement. Most engineers treat “nylon” as a single material when assessing chemical compatibility, then are surprised when PA6 and PA12 behave dramatically differently in the same environment.
This guide provides systematic chemical resistance data for PA6, PA66, and PA12 across all major chemical classes, with clear guidance on when nylon is appropriate and when alternative materials should be specified.
Understanding Nylon Chemical Resistance Mechanisms
Nylon resistance to chemicals operates through three distinct mechanisms. Understanding which mechanism applies to your environment determines whether the material will perform reliably.
Physical resistance: The polymer matrix physically blocks chemical penetration. This is the dominant mechanism for non-polar solvents like gasoline and oils — nylon has excellent resistance because hydrocarbon molecules cannot penetrate the crystalline domains.
Chemical resistance: The polymer chain does not react with the chemical. This is why nylon is attacked by strong acids and bases — they hydrolyze the amide bonds in the polyamide chain.
Plasticization and swelling: Water and polar solvents penetrate the amorphous regions, swelling the polymer without breaking chemical bonds. This increases flexibility but reduces stiffness and dimensional accuracy.
| Chemical Class | PA6 | PA66 | PA12 | Primary Mechanism | Application Notes |
|---|---|---|---|---|---|
| Motor oils (mineral) | Excellent | Excellent | Excellent | Physical barrier | Under-hood auto applications |
| Motor oils (synthetic) | Excellent | Excellent | Excellent | Physical barrier | ATS, DCT fluids |
| Gasoline (aromatic) | Good (60°C) | Good (100°C) | Excellent | Physical barrier | Fuel rails: PA66-GF30 |
| Ethanol blends (E85) | Limited | Limited (80°C) | Excellent | Physical + swelling | Fuel lines: PA12 preferred |
| Diesel, Biodiesel | Bon | Bon | Excellent | Physical barrier | Fuel system components |
| ATF / Transmission fluid | Good (120°C) | Excellent (150°C) | Bon | Physical barrier | Transmission oil pans |
| Glycol coolant (50/50) | Good (100°C) | Good (130°C) | Excellent | Swelling (limited) | Coolant reservoirs |
| Brake fluids (DOT 3/4/5) | Pauvre | Pauvre | Bon | Chemical attack | Use PA12 for brake components |
| Weak acids (<10%) | Limited (elev T) | Limited (elev T) | Bon | Chemical hydrolysis | PA12 or PP for acid contact |
| Strong acids (>10%) | Not recommended | Not recommended | Limited | Rapid hydrolysis | PVDF or PTFE for acid |
Water Absorption and Its Effect on Chemical Resistance
Moisture absorption fundamentally changes nylon’s chemical resistance profile. Dry nylon is more chemically resistant to polar solvents (the plasticized, wet state actually resists further polar penetration) but is more susceptible to oxidative degradation. This creates a critical design consideration: parts in wet service should be tested in the conditioned (wet) state, not dry-as-molded.
| Conditioning State | PA6 Tensile Strength | PA6 Modulus | Chemical Resistance to Water | Chemical Resistance to Acids |
|---|---|---|---|---|
| Dry as molded (0%) | 85 MPa | 3,200 MPa | N/A | Poor (brittle failure) |
| Conditioned 50% RH (2.5%) | 65 MPa | 2,000 MPa | Moderate | Moderate (ductile) |
| Saturated (9.0%) | 45-50 MPa | 1,200 MPa | Swells significantly | Moderate (ductile) |
| After drying (0.1%) | 80+ MPa | 3,000 MPa | Excellent | Poor (brittle failure) |
Industrial and Laboratory Chemical Environments
For chemical processing and industrial equipment, verify compatibility under actual operating conditions with immersion testing. The following table provides baseline guidance for common industrial chemicals.
| Chemical | PA6 | PA66 | PA12 | Max Service Temp (°C) | Alternative Material |
|---|---|---|---|---|---|
| Sulfuric acid (10%) | Limited | Not recommended | Limited | 40°C | PVDF, HDPE |
| Hydrochloric acid (10%) | Not recommended | Not recommended | Limited | 40°C | PVDF, PTFE |
| Sodium hydroxide (50%) | Limited (>60°C) | Not recommended | Bon | 80°C | PP, HDPE |
| Acetone | Limited | Not recommended | Bon | 60°C | PTFE |
| Ethanol | Bon | Bon | Excellent | 100°C | PA12 de préférence |
| Phenol (5%) | Not recommended | Not recommended | Not recommended | N/A | PTFE only |
| Formic acid (10%) | Not recommended | Not recommended | Limited | 40°C | PTFE, PVDF |
| Calcium chloride | Limited | Limited | Bon | 80°C | PA12 for salt contact |
| Steam (continuous) | Not recommended | Not recommended | Limited | 120°C | PPS, PTFE |
Automotive Fluids: The Most Common Real-World Exposure
Automotive under-hood applications define the largest volume of nylon use globally. The following data reflects ASTM D543 immersion testing results at specified temperatures and exposure durations (typically 1,000 hours = approximately 6 weeks of continuous exposure).
| Fluide | PA6 | PA66 | PA12 | Weight Change | Tensile Retention | Application Confidence |
|---|---|---|---|---|---|---|
| Engine oil SAE 5W-30 (150°C) | Excellent | Excellent | Excellent | <1% | >95% | Full production use |
| Transmission fluid ATF (130°C) | Bon | Excellent | Bon | <2% | >90% | Full production use |
| Power steering fluid (120°C) | Bon | Bon | Excellent | <2% | >90% | Full production use |
| Coolant 50/50 EG (130°C) | Bon | Bon | Excellent | <3% | >85% | Full production use |
| Brake fluid DOT 4 (120°C) | Pauvre | Pauvre | Bon | >10% | <60% | PA12 only |
| Windshield washer (60°C) | Excellent | Excellent | Excellent | <0.5% | >99% | Full production use |
| Battery acid (25°C) | Not recommended | Not recommended | Not recommended | N/A | N/A | PP or PE only |
| AdBlue / DEF (urea) | Bon | Bon | Excellent | <1% | >95% | SCR system components |
FAQ
Comment savoir si la résistance chimique du nylon : Acides, Bases, Solvants, et autres, correspond à un besoin ?
Résistance chimique du nylon : Acides, bases, solvants et autres convient à une pièce lorsque sa capacité de charge, sa plage de températures, son exposition à l'humidité, son comportement à l'usure et sa méthode de traitement correspondent aux conditions de service réelles.
Quelles sont les propriétés à vérifier pour la résistance chimique du nylon : Acides, bases, solvants et autres ?
Vérifier la résistance, la rigidité, la résistance aux chocs, la résistance à la chaleur, l'absorption d'humidité, la stabilité dimensionnelle, le frottement, l'usure et la compatibilité chimique.
Quel est le plus grand risque de sélection pour Nylon Chemical Resistance : Acides, bases, solvants et autres ?
Le plus grand risque est de choisir à partir d'une fiche technique sans tenir compte de l'environnement réel, de la méthode de traitement, de la géométrie de la pièce et de l'utilisation à long terme.
Quand faut-il tester la résistance chimique du nylon : Acides, bases, solvants et autres doit-il être testé avant la production ?
Les essais sont recommandés lorsque la pièce est soumise à une charge, à la chaleur, à des produits chimiques, à l'humidité, à des tolérances serrées, à des exigences réglementaires ou à un nouvel environnement de travail.
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