Your search keyword '"Eccentric rheometry"' showing total 2 results

1. Miniaturized characterization of polymers: from synthesis to rheological and mechanical properties in 30 mg

Author

Ruth Cardinaels, S. Petisco-Ferrero, L.C.A. van Breemen, and Processing and Performance

Subjects

Materials science, Polymers and Plastics, YIELD-STRESS, PHASE, Polymer Science, Mechanical performance, PROCESSING-INDUCED PROPERTIES, Miniaturized testing, RELAXATION, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Eccentric rheometry, Rheology, GLASSY-POLYMERS, Materials Chemistry, Torque, Composite material, TEMPERATURE, chemistry.chemical_classification, Science & Technology, Rheometry, Organic Chemistry, Polymer, ALIPHATIC POLYESTERS, 021001 nanoscience & nanotechnology, Aspect ratio (image), COPOLYMERS, 0104 chemical sciences, Characterization (materials science), Polycaprolactone, chemistry, Physical Sciences, Deformation (engineering), 0210 nano-technology, Material properties, POLYCAPROLACTONE SCAFFOLDS, BEHAVIOR

Abstract

The determination of rheological and mechanical material properties becomes a challenge when the availability of material is limited to a few (milli)grams. This miniaturized testing is hampered by the contradicting requirements of small sample sizes (and thus surface areas) and sufficiently large generated torques and forces. In this paper we provide a feasible methodology to determine the relevant material parameters in terms of processing and mechanical performance starting from 30 mg of material, using micropillars with a diameter of 1 mm. Complex viscosity in small amplitude oscillatory shear as the relevant parameter for thermoconformation processes is determined by means of eccentric rheometry. Herein, the sample is placed off-centered, which results in an increase in the generated torque without the need for increasing the size of the sample. By combining experimental data and numerical simulations, we show that the choice of the pillar aspect ratio is essential to maintain a homogeneous sample deformation and thus to extract correct rheological parameters. Values obtained with eccentric rheometry collapse with those obtained from standard rheometry. The intrinsic mechanical behavior is evaluated at room temperature and the yielding kinetics is studied. The methodology developed here can be extended to other systems and testing conditions, allowing a full material characterization in the liquid as well as in the solid state with only 30 mg of material.

Published

2019

2. Miniaturized characterization of polymers: From synthesis to rheological and mechanical properties in 30 mg.

Author

Petisco-Ferrero, S., Cardinaels, R., and van Breemen, L.C.A.

Subjects

*POLYMERIZATION, *MECHANICAL behavior of materials

Abstract

The determination of rheological and mechanical material properties becomes a challenge when the availability of material is limited to a few (milli)grams. This miniaturized testing is hampered by the contradicting requirements of small sample sizes (and thus surface areas) and sufficiently large generated torques and forces. In this paper we provide a feasible methodology to determine the relevant material parameters in terms of processing and mechanical performance starting from 30 mg of material, using micropillars with a diameter of 1 mm. Complex viscosity in small amplitude oscillatory shear as the relevant parameter for thermoconformation processes is determined by means of eccentric rheometry. Herein, the sample is placed off-centered, which results in an increase in the generated torque without the need for increasing the size of the sample. By combining experimental data and numerical simulations, we show that the choice of the pillar aspect ratio is essential to maintain a homogeneous sample deformation and thus to extract correct rheological parameters. Values obtained with eccentric rheometry collapse with those obtained from standard rheometry. The intrinsic mechanical behavior is evaluated at room temperature and the yielding kinetics is studied. The methodology developed here can be extended to other systems and testing conditions, allowing a full material characterization in the liquid as well as in the solid state with only 30 mg of material. Image 1 • A methodology for the full characterization of laboratory batches of new materials is presented. • Rheological parameters are extracted from eccentric rheometry. • Screening of new materials for load bearing applications is described. • Mechanical performance is correlated to processing-induced microstructure. • The intrinsic mechanical behavior of PCL is documented. [ABSTRACT FROM AUTHOR]

Published

2019