Glass Transition Temperature (Tg): When Rubber Becomes Brittle as Glass
Problem Statement
High-temperature applications expose rubber components to thermal stress, leading to brittleness and failure. A client reported premature cracking in EPDM seals operating at 120°C, below the material’s rated maximum temperature of 150°C. Root cause analysis identified the glass transition temperature (Tg) as the critical factor.
Material Science Analysis
At Tg, rubber transitions from a flexible, elastomeric state to a rigid, glass-like state. EPDM’s Tg (-50°C to -40°C) is low, but its molecular structure lacks resistance to oxidative degradation at elevated temperatures. FKM, with a Tg of -20°C to 0°C, outperforms EPDM due to its fluorine content, which provides superior thermal stability and chemical resistance.
Technical Specs
- Material: FKM (Fluorocarbon Rubber)
- Shore A Hardness: 70-90
- Tensile Strength: 15-20 MPa
- Elongation at Break: 100-200%
- Temperature Range: -20°C to 200°C
- Compression Set: ≤20% (22 hrs at 200°C)
Technical Comparison
| Material | Tg (°C) | Temperature Range (°C) | Chemical Resistance | Compression Set (%) |
|---|---|---|---|---|
| FKM | -20 to 0 | -20 to 200 | Excellent | ≤20 |
| EPDM | -50 to -40 | -50 to 150 | Good | ≤30 |
| Silicone | -120 to -100 | -60 to 230 | Fair | ≤25 |
Standard Compliance
RubberQ adheres to IATF 16949 standards for batch-to-batch consistency. Our in-house compounding ensures precise control over polymer ratios, fillers, and curing agents. Materials meet ASTM D2000 for performance and ISO 3601 for sealing applications.
CTA
For custom material compound development or IATF 16949 documentation, consult RubberQ’s engineering department.
Technische Updates abonnieren
Erhalten Sie neue Material-Insights und Engineering-Notizen per E-Mail.
Verwandte Artikel
05. Apr. 2026
Liquid Silicone Rubber (LSR) Tooling: Why Initial Investment Pays Off in Precision.
Liquid Silicone Rubber (LSR) Tooling: Why Initial Investment Pays Off in Precision Problem Statement High-cycle manufacturing of precision components, such as EV battery seals and AI server gaskets, demands materials with exceptional dimensional stability and chemical resistance. Traditional elastomers like EPDM and NBR often fail under extreme thermal cycling and aggressive chemical exposure, leading to […]
Artikel lesen05. Apr. 2026
High-Tonnage Vulcanization: Managing Large-Scale Industrial Rubber Components.
High-Tonnage Vulcanization: Managing Large-Scale Industrial Rubber Components Problem Statement Large-scale industrial rubber components, such as conveyor belts and hydraulic seals, face premature failure under high-tonnage vulcanization. Common issues include chemical degradation at temperatures exceeding 200°C and compression set failure during high-pressure cycles. Material Science Analysis Standard EPDM polymers fail under extreme heat due to their […]
Artikel lesen05. Apr. 2026
Commercial Aircraft Interiors: Meeting Smoke and Toxicity Standards (FST).
Commercial Aircraft Interiors: Meeting Smoke and Toxicity Standards (FST) Problem Statement Polymer components in aircraft interiors must pass FAR 25.853 flammability tests while maintaining mechanical performance. Standard EPDM fails at 180°C with toxic smoke emission (HCN >100 ppm). Material Science Analysis Chloroprene rubber (CR) releases HCl gas during combustion. Fluorosilicone (FVMQ) provides superior thermal stability […]
Artikel lesenBenötigen Sie technische Beratung?
Unser Ingenieurteam kann Ihnen helfen, diese Materialerkenntnisse auf Ihr spezifisches Projekt anzuwenden.
ANGEBOT ANFORDERN