SAE AIR1387D
Current
The latest, up-to-date edition.
Designing with Elastomers for use at Low Temperatures, Near or Below Glass Transition
Hardcopy , PDF
English
15-01-2016
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1. SCOPE
2. REFERENCES
3. SUMMARY
4. TERMINOLOGY
5. TRANSITIONS IN ELASTOMERS
6. GLASS TRANSITION TEMPERATURE (Tg)
7. PLASTICIZERS AND THE GLASS TRANSITION (Tg)
8. VISCOELASTIC EFFECT
9. CRYSTALLIZATION TRANSITIONS
10. RESPONSE TO SUDDEN TRANSIENT SHEAR
STRESS
11. PRACTICAL LOW TEMPERATURE TEST METHODS
FOR ELASTOMERS
12. NOTES
To ensure success in design of elastomeric parts for use at low temperature, the design engineer must understand the peculiar properties of rubber materials at these temperatures.
| DocumentType |
Standard
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| Pages |
16
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| PublisherName |
SAE International
|
| Status |
Current
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| Supersedes |
To ensure success in design of elastomeric parts for use at low temperature, the design engineer must understand the peculiar properties of rubber materials at these temperatures.There are no static applications of rubber. The Gaussian theory of rubber elasticity demonstrates that the elastic characteristic of rubber is due to approximately 15% internal energy and the balance, 85%, is entropy change. In other words, when an elastomer is deformed, the elastomer chain network is forced to rearrange its configuration thereby storing energy through entropy change. Thermodynamically, this means that rubber elasticity is time and temperature dependent (Reference 25).The purpose of this report is to provide guidance on low temperature properties of rubber with the terminology, test methods, and mathematical models applicable to rubber, and to present some practical experience. In this way, it is hoped that mistakes can be avoided, particularly in selection of rubber materials, enabling the design engineer to weigh low-temperature material properties together with the many other factors involved in the design process.
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| NAS 1613 : 2002 | PACKING, PREFORMED, ETHYLENE PROPYLENE RUBBER |
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| ASTM D 832 : 2007 : R2018 | Standard Practice for Rubber Conditioning For Low Temperature Testing |
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| SAE AMS7257E | Perfluorocarbon (FFKM) Engine Oil, Fuel and Hydraulic Fluid Resistant 70 to 80 Hardness For High Temperature Seals in Engine Oil Systems, Fuel Systems and Hydraulic Systems |
| SAE AMS3218C | Fluorocarbon (FKM) Rubber High-Temperature-Fluid Resistant Low Compression Set 85 to 95 |
| SAE AMS7255D | Rings, Sealing, Tetrafluoroethylene/Propylene Rubber (FEPM) Hydraulic Fluid and Synthetic Oil Resistant 70 to 80 |
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| SAE AMS7270L | Rings, Sealings, Butadiene-Acrylonitrile (NBR) Rubber Fuel Resistant 65 – 75 |
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| ASTM D 1329 : 2016 : REDLINE | Standard Test Method for Evaluating Rubber Property—Retraction at Lower Temperatures (TR Test) |
| SAE AMS3238H | Butyl (IIR) Rubber Phosphate Ester Resistant 65 - 75 |
| MIL-DTL-25988 Revision C:2006 | RUBBER, FLUOROSILICONE ELASTOMER, OIL- AND FUEL-RESISTANT, SHEETS, STRIPS, MOLDED PARTS, AND EXTRUDED SHAPES |
| SAE AMS3209M | Chloroprene (CR) Rubber Weather Resistant 65 - 75 |
| SAE AMS3337E | Silicone (PVMQ) Rubber Extreme-Low-Temperature Resistant 65 - 75 |
| ASTM D 746 : 2014 : REDLINE | Standard Test Method for Brittleness Temperature of Plastics and Elastomers by Impact |
| ASTM D 1418 : 2017 : REDLINE | Standard Practice for Rubber and Rubber Latices—Nomenclature |
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