Influence of Programming and Recovery Parameters on Compressive Behaviors of 4D‐Printed Biocompatible Polyvinyl Chloride or Vinyl–Poly(ε‐Caprolactone) Blends

Author:

Rahmatabadi Davood1ORCID,Aberoumand Mohammad1,Soltanmohammadi Kianoosh1,Soleyman Elyas1,Ghasemi Ismaeil2,Baniassadi Majid1,Abrinia Karen1,Bodaghi Mahdi3ORCID,Baghani Mostafa1ORCID

Affiliation:

1. School of Mechanical Engineering College of Engineering University of Tehran Tehran 1417614411 Iran

2. Faculty of Processing Iran Polymer and Petrochemical Institute Tehran 1497713115 Iran

3. Department of Engineering School of Science and Technology Nottingham Trent University Nottingham NG11 8NS UK

Abstract

In this article, a new class of biocompatible shape‐memory polymers (SMPs) through blending pcolyvinyl chloride or vinyl (PVC) and poly(ε‐caprolactone) (PCL) is introduced. The compressive shape‐memory behaviors of 4D‐printed SMP PVC with 5 and 10 wt% of PCL are studied in detail. In this respect, a set of experiments are carried out to understand thermomechanical responses of PVC–PCL blends under various shape‐memory parameters like programming temperature, load‐holding time, applied strain, and recovery temperature. Dynamic mechanical thermal analysis and scanning electron microscope imaging are also performed to provide thermal and morphological analyses. It is found that by raising the recovery temperature from 45 to 65 °C, the shape recovery ratio increases from 5.63 to 7.92 MPa when the PVC–PCL10 is programmed via the hot‐programming (HP) protocol. The highest level of shape fixity (100%) and the best performance of stress relaxation are achieved for HP sample, while the highest shape recovery ratio (100%) is obtained for cold programming. By applying the load‐holding time, the amount of shape fixity can reach from 88.14% to 100%. Results of this research are expected to provide an insightful understanding of the shape‐memory behaviors of PVC–PCL and be instrumental for 4D printing and programming of shape‐adaptive structures like shape‐memory intervertebral cages as spinal support devices.

Publisher

Wiley

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