The researchers at the Fraunhofer WKI and Fraunhofer IAP furthermore conducted tests into the compounding of non-reinforced biopolymers and wood-particle-reinforced biopolymers with halogen-free, currently available flame retardants. They were able to determine that these are procedurally suitable for PLA and bio-based polybutylene succinate (PBS) as base polymers. In the processing of PLA, the use of a heatable mold is required in order to achieve high crystallinities and, consequently, high thermal stability in the components. In addition to good flame retardancy, thermal stability is an important criterion for the application. The team succeeded in developing formulations for PLA and PBS which fulfill, to a large extent, the flame-retardancy requirements in the target applications and which can be processed via injection molding and additive manufacturing. This was demonstrated through various tests, including UL94, glow-wire testing, and tracking-resistance testing.
The processing results obtained through injection molding at the participating industrial partners are very encouraging. It was possible for technical flame-retardant components and parts – such as flexible adaptors for switch boxes and storage containers from the logistics sector – to be manufactured under near-production conditions. For the PBS-based materials, the cycle times lie within a range which is comparable to the petro-based plastics in use today.
In the experiments with the addition of wood particles, the researchers were furthermore able to demonstrate that these have a positive influence on the flame-retardant performance. The heat-release rates were significantly reduced through the addition of wood. Simultaneously, however, there was a shortening of the ignition times. For wood-fiber-reinforced, flame-retardant and crystallized PLA compounds, a maximum thermal stability of 140 °C to 160 °C was verified.