Understanding moisture absorption in nylon — how it affects mechanical properties, dimensional stability, processing, and design strategies to manage it.
Nylon’s Moisture Sensitivity: A Critical Design Variable
Of all common engineering thermoplastics, nylon absorbs the most moisture. PA6 reaches 9.5% by weight at saturation, while PA66 reaches 8.5%. This is not a minor property — it fundamentally alters the material’s mechanical behavior, dimensions, electrical properties, and appearance.
Designers and engineers who ignore moisture absorption face a common failure mode: parts that fit perfectly when molded (dry) but swell, distort, or change flexibility after exposure to normal humidity. A nylon gear that meshes perfectly in the factory may bind and wear prematurely in a humid warehouse. Understanding and controlling moisture effects is essential for reliable nylon part design.
Mechanism: How Nylon Absorbs Water
Nylon’s molecular structure contains amide groups (-CONH-) that form hydrogen bonds with water molecules. This is the same hydrogen-bonding mechanism that makes nylon strong in the first place — but water molecules occupy hydrogen-bonding sites that were previously linking nylon chains together, reducing inter-chain forces.
**Absorption Rate**:
The rate of moisture absorption depends on thickness and humidity:
| 1mm film | 2 hours | 8 hours |
|---|
| 2mm sheet | 8 hours | 36 hours |
|---|---|---|
| 6mm plate | 3 days | 12 days |
This is why thin-walled parts reach equilibrium faster — and why thick sections can retain dry conditions in the core while the surface is saturated.
**Drying Reverses the Process**:
Heating nylon above 80°C drives off absorbed moisture. At 100°C for 4-6 hours, PA6 and PA66 reach dry-as-molded condition. However, the dimensional changes from drying are not fully reversed — the part does not shrink back to its dry-molded dimensions because the polymer chains have reorganized.
Effects on Mechanical Properties
| Treksterkte | 95 MPa | 75 MPa | -21% |
|---|---|---|---|
| Tensile Modulus | 3.2 GPa | 2.0 GPa | -37% |
| Flexural Modulus | 3.0 GPa | 1.8 GPa | -40% |
| Rek bij breuk | 80% | 180% | +125% |
|---|---|---|---|
| Hardness (Shore D) | 82 | 74 | -10% |
**Key insight**: Moisture acts as a plasticizer for nylon. The material becomes softer, weaker in tension and flexure, but significantly tougher. Impact resistance nearly doubles in conditioned nylon vs. dry nylon.
**Design Implication**: If you design to dry property values, your conditioned parts will be 20-40% weaker than calculated. Always design to the highest moisture condition the part will experience in service.
**Glass fiber reinforcement mitigates moisture effects** — GF30 grades show only 10-15% strength reduction from dry to conditioned (vs. 20-25% for unfilled). The glass fiber network is unaffected by moisture; only the nylon matrix is plasticized.
Dimensional Effects and Warpage
Moisture absorption causes linear expansion in nylon:
**Dimensional Change from Dry to Saturated**:
| Rang | Linear Expansion per % Moisture |
|---|---|
| PA6 | 0.25-0.30% |
| PA66 | 0.22-0.28% |
| PA12 | 0.12% |
|---|---|
| PA66-GF30 | 0.07% |
A PA6 bushing with 50mm OD, molded dry, will expand to approximately 50.35mm at 50% RH saturation (0.35% change × 50mm = 0.175mm). If the assembly requires 50.0-50.1mm fit, this is a critical tolerance issue.
**Unequal Moisture Distribution Causes Warpage**:
In thick sections, the outer surface absorbs moisture while the core remains dry. This creates differential swelling — the surface wants to expand while the core resists. The result is warpage (bowing, distortion) even in parts with symmetrical geometry.
**Design Strategies**:
1. **Anneal before final dimensioning** — Heat treat parts at 120-130°C for 1-2 hours to crystallize and stabilize dimensions before machining or assembly
2. **Condition to equilibrium** — Allow parts to reach uniform moisture content before final assembly
3. **Use GF or CF reinforcement** — Fiber reinforcement reduces moisture-induced expansion by 70-80%
4. **Specify PA12** — At 1.5% saturation vs. 8-9% for PA6/66, PA12’s dimensional change is negligible
Processing: Drying Requirements
Excess moisture in nylon during injection molding causes catastrophic defects:
**Moisture Defects**:
– **Bubbles and voids**: Steam formed during injection creates internal voids
– **Silver streaks**: Water vapor flashing off during injection creates surface streaks
– **Reduced molecular weight**: Hydrolysis during processing weakens the material
– **Reduced mechanical properties**: Even if surface looks good, the material is degraded
**Required Drying Parameters**:
| Materiaal | Drying Temperature | Drying Time | Max Moisture Content |
|---|---|---|---|
| PA6 | 80°C | 4-6 uur | 0.20% |
| PA66 | 80-85°C | 4-6 uur | 0.15% |
| PA12 | 80°C | 3-4 hours | 0.10% |
|---|---|---|---|
| PA66-GF30 | 85°C | 4-6 uur | 0.12% |
**Drying Equipment**: Desiccant dryers are mandatory for nylon. Hot air dryers are insufficient because they cannot remove moisture below the surface. Desiccant dryers with dew point below -40°C are required.
**Moisture Analyzers**: Use Karl Fischer titration or loss-on-drying to verify material moisture before processing critical parts. Most production facilities check every batch.
PA12 vs. PA6/PA66: When to Choose Low-Moisture Grades
For applications where moisture is unavoidable, PA12 is the logical choice:
**Applications where PA12’s low absorption is essential**:
– **Underwater or marine components**: PA12 maintains properties in submerged conditions where PA6/66 would absorb 5-8%
– **Outdoor exposed parts**: PA12’s 1.5% saturation vs. 8-9% means far less dimensional change through seasonal humidity cycles
– **Food processing (steam cleaning)**: PA12 resists steam exposure better than PA6/66
– **Fluid metering components**: Dimensional stability in humid air is critical for precision metering
– **Cable conduits**: PA12 handles underground moisture without swelling
**Cost vs. Benefit**:
PA12 costs approximately 2-3× more than PA66. The premium is justified when:
1. Field failures from moisture-induced swelling are costly
2. Dimensional tolerances are tight (±0.05mm or tighter)
3. The part is exposed to water, humidity, or steam
4. Assembly requires parts at equilibrium condition before fit testing
**Hybrid Approach**:
For many applications, PA66-GF30 achieves a practical balance: the glass fiber reinforcement reduces moisture absorption by ~70% (effective absorption drops from 8.5% to ~2.5%), and the GF network limits dimensional change. This is why PA66-GF30 is the automotive default — it handles under-hood humidity without the premium cost of PA12.
FAQ
How do you know whether Moisture Absorption in Nylon: Effects, Measurement, and Control fits a part?
Moisture Absorption in Nylon: Effects, Measurement, and Control fits a part when its load capacity, temperature range, moisture exposure, wear behavior, and processing method match the real service conditions.
What properties should be checked for Moisture Absorption in Nylon: Effects, Measurement, and Control?
Check strength, stiffness, impact resistance, heat resistance, moisture absorption, dimensional stability, friction, wear, and chemical compatibility.
What is the biggest selection risk for Moisture Absorption in Nylon: Effects, Measurement, and Control?
The biggest risk is choosing from a datasheet value without considering actual environment, processing method, part geometry, and long-term use.
When should Moisture Absorption in Nylon: Effects, Measurement, and Control be tested before production?
Testing is recommended when the part faces load, heat, chemicals, moisture, tight tolerances, regulatory requirements, or a new operating environment.
English
Dutch
German
French
Korean
Russian
Japanese
Spanish
Vietnamese
Chinese
Portuguese
Arabic