Humidity and thermal triggered Shape Memory Effect - Rheology-based numerical modelling - Dynamic Mechanical Thermal Humidity Analysis

DOI

This data contains iso-thermal and iso-humid shear frequency-sweep measurements of Shape Memory Polymers (SMP). The SMP is a polyurethane-based Polymer, which is produced from SMP Technologies Inc. The SMP filament were processed with a 3D printer (Ultimaker 3, Ultimaker, Geldermarsen, Netherlands).

Frequency-sweeps were performed in a temperature range (5 °C - 85 °C) and at relative humidity 0 %, 30 %, 50 %, 70 % and 100 %. A preheating step was performed before each frequency measurement to relieve residual stresses stored by the manufacturing process. Subsequently, at a temperature T = 60 °C above the glass transition temperature (T_G), the relative humidity is set and held for 5 days to fully saturate the sample. After that, the sample is slowly cooled down to 10 °C in order not to store residual stresses in the sample. The sample geometry is measured again and then the actual frequency measurement is performed.

The frequency measurements are performed in the frequency range from 0.01 Hz to 10 Hz at isothermal and isohumid conditions. The shear strain amplitude is set below T_G with gamma = 0.1 % and above T_G with gamma = 0.2 %. The sample is drawn below T_G with a normal force of F_N = - 0.4 N and above T_G with a normal force of F_N = - 0.2 N. So that the specimen is always drawn and does not bend, which affects the shear measurements.

With the results of the isothermal and isohumid frequency measurements, on the one hand, temperature shifts at different humidities can be presented. The temperature shifts are used to determine the humidity-dependent T_Gs. On the other hand, master curves can be determined at different humidities. With the humidity-dependent master curves, the viscoelastic material behavior is determined in a larger frequency range (Time-Temperature Superpositon). In addition, the shift parameters (alpha_T) determined for the master curves are included.

The data is organized in the following folder structure, e.g. dynamic thermal humid analysis at dry condition = dmtha_dry.

dmtha_dry

frequency_sweep_SMP_dry mastercurve_SMP_dry alpha_T_dry

dmtha_redry

frequency_sweep_SMP_redry mastercurve_SMP_redry alpha_T_redry

dmtha_30

frequency_sweep_SMP_30 mastercurve_SMP_30 alpha_T_30

dmtha_50

frequency_sweep_SMP_50, mastercurve_SMP_50, alpha_T_50

dmtha_70

frequency_sweep_SMP_70 mastercurve_SMP_70 alpha_T_70

dmtha_wet

frequency_sweep_SMP_wet mastercurve_SMP_wet alpha_T_wet

Identifier
DOI https://doi.org/10.18419/darus-2021
Related Identifier https://doi.org/10.1007/s10853-022-07206-8
Metadata Access https://darus.uni-stuttgart.de/oai?verb=GetRecord&metadataPrefix=oai_datacite&identifier=doi:10.18419/darus-2021
Provenance
Creator Fauser, Dominik ORCID logo; Steeb, Holger ORCID logo
Publisher DaRUS
Contributor Steeb, Holger; University of Stuttgart, Institute of Applied Mechanics (CE) - Chair for Continuum-Mechanics; University of Stuttgart - Cluster of Excellence EXC 2075 "SimTech"; Fauser, Dominik
Publication Year 2021
Rights CC BY 4.0; info:eu-repo/semantics/openAccess; http://creativecommons.org/licenses/by/4.0
OpenAccess true
Contact Steeb, Holger (University of Stuttgart, Institute of Applied Mechanics (CE) & SC SimTech)
Representation
Resource Type Dataset
Format text/tab-separated-values
Size 607; 506; 431; 483; 518; 385; 53839; 40735; 49257; 41994; 41921; 41126; 25000; 20463; 16390; 23346; 22309; 15216
Version 1.1
Discipline Chemistry; Construction Engineering and Architecture; Earth and Environmental Science; Engineering; Engineering Sciences; Environmental Research; Geosciences; Mechanical and industrial Engineering; Mechanics; Mechanics and Constructive Mechanical Engineering; Natural Sciences; Physics