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| Bio-Polyamides Part 5: performance review. |
Hello and welcome to the fifth part of our Bio-Polyamide series.
Check out Part 1, Part 2, Part 3, and Part 4 too.
In this post we discuss how to differentiate the performance of Bio-Polyamides in order to support you in your next polymer material selection project.
A brief re-cap of Bio-Polyamides
In general we can distinguish between short- and long-chain aliphatic homo- and copolymer Polyamides. The term bio-based covers bio-based, biomass balanced or recycled content.
PA 5.6 is the main Bio-Polyamide among the short-chain Polyamides and the pentamethylene diamine needed can be derived from biomass or sugar.
Bio-PA 6 uses starch or sugar as base feedstock and over a fermentation process, caprolactam is obtained. Bio-PA 6 can be also mass-balanced and therefore used as a drop-in solution for replacing fossil based PA 6 allowing to reduce the carbon footprint from 6.7 CO2 eq/kg. to 4.52 kg CO2 eq/kg.
For aliphatic long-chain homo- and copolymer Bio-Polyamides, castor oil is used to make sebacic acid. In case of PA 6.10 and PA 11, sebacic acid represents the 10 share of PA 6.10. In the case of PA 10.10, the first 10 is based on decamethylene diamine (DMDA) and the second 10 is again from sebacic acid. Obtaining DMDA is achieved by nitrile synthesis of sebacic acid. Standard Polyamides such as PA 6.6 and PA 12 can be replaced with such bio-based materials.
Table 1 summarises the differences.
Table 1: Overview differences in chemical structure of Bio-Polyamides [1].
| Bio-Polyamide | Monomer 1 | Monomer 2 | Raw material | Bio-based carbon content (%) |
|---|---|---|---|---|
| Polyamide 6 (PA 6) | ε-Caprolactam (mass-balanced) | ε-Caprolactam (mass-balanced) | Tall oil | Mass-balanced |
| Polyamide 6.10 (PA 6.10) | Hexamethylendiamine | Sebacic acid (bio-feedstock) | Castor oil | 62 % |
| Polyamide 5.6 (PA 5.6) | Pentamethylendiamine (bio-feedstock) | Adipic acid | Corn | 41 % |
| Polyamide 11 (PA 11) | 11-Aminoundecaoic acid (bio-feedstock) | 11-Aminoundecaoic acid (bio-feedstock) | Castor oil | 92 % |
Table 2: Performance overview of Bio-Polyamides [4].
| Bio-Polyamide | Bio-sourcing (% of C-Atom) | GWP (kg CO2eq/kg) | Glass transition temperature Tg (°C) | Tensile strength (MPa) | Tensile Modulus (MPa) | Water adsorption (%) |
|---|---|---|---|---|---|---|
| Polyamide 6.10 (PA 6.10) | 63 | 4.6 | 48 | 61 | 2100 | 2.9 |
| Polyamide 10.10 (PA 10.10) | 100 | 4 | 37 | 54 | 1800 | 1.8 |
| Polyamide 10.12 (PA 10.12) | 45 | 5.2 | 49 | 40 | 1400 | 1.6 |
| Polyamide 11 (PA 11) | 100 | 4.2 | 42 | 34 | 1100 | 1.9 |
| Polyamide 10T (PA 10T) | 50 | 6.9 | 125 | 73 | 2700 | 3 |
| Polyamide 12 (PA 12) | 0 | 6.9 | 138 | 45 | 1400 | 1.5 |
| Polyamide 6 (PA 6) | 0 | 9.1 | 47 | 80 | 3000 | 10.5 |
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| Figure 1: elastic modulus E’ obtained by DMA of short- and long-chain aliphatic Polyamides [6]. |
Thanks for reading and #findoutaboutplastics!
Greetings
Herwig Juster
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