Melt Processing of a New Biodegradable Synthetic Polymer in High-Speed Spinning and Underpressure Spunbonding Process

A new biodegradable synthetic polyesteramid (PEA) was characterized by means of thermogravimetry (TG) differential scanning calorimetry (DSC) and dynamic rheological measurements. Two glass transition ranges at about –33 and 38°C and a melting enthalpy of 33 J/g were measured, indicating that PEA is an immiscible blend of two components with a small crystalline part. The material was spun in a high-speed spinning process within the range of 2,000–6,000 M/min and an underpressure spunbonding process within the range of 3,600–7,700 M/min. The textile physical properties of the fibers were 100 MPa tenacity at an elongation at break of 30%, and an E-modulus of 0.5 GPa. The mass per unit area of the spunbonded nonwovens ranged from 70–159 g/M ². The strength of the spunbonded nonwovens was 28–51 N and 42–74 N in machine and cross direction, respectively. The air permeability of the nonwovens decreased at high air velocities and more fineness of the filaments from 1240–380 l/M ² s.     

Large-scale production of poly(3-hydroxyvaleric acid) by fermentation ofChromobacterium violaceum,processing, and characterization of the homopolyester

A fed-batch process was developed, which allowed biotechnological production of the homopolyester poly(3-hydroxyvaleric acid) [poly(3HV)], in a mineral salts medium containing valeric acid as carbon source and complex nutrients as supplements byChromobacterium violaceum at a 10- and 300-L fermentation scale. This process yielded up to 40 g dry cell matter per L fermentation broth, and the cells contained up to 70% (w/w) poly(3HV). Poly(3HV), which was extracted from the cells with chloroform and was precipitated from this solvent with ethanol, was processed to test bars by injection molding or by press processing and to fibers by melt spinning. The unprocessed and processed poly(3HV) material was characterized with respect to the molecular weight and with respect to thermal, rheological, and mechanical properties. It was shown that it is possible to process biodegradable poly(3HV) thermoplastically and to obtain a polymer suitable for applications with low strength requirements.