Skip to Content
MilliporeSigma
All Photos(1)

Documents

900984

Sigma-Aldrich

Flexible Thermoplastic Copolyester (TPC) Printing Filament

1.75mm, red

Synonym(s):

FlexiFil, TPC filament

Sign Into View Organizational & Contract Pricing


About This Item

UNSPSC Code:
12162002
NACRES:
NA.23

description

Filament diameter: 1.75 ± 0.05 mm
Filament roundness: ≥95%
Melt flow rate: 39 cc/10 min
Melt temperature: ±180 °C
Print temperature: ±220-260 °C
Specific gravity: 1.14 g/cc
Spool Hub Diameter: 52 mm
Spool Size (D x H): 200 mm x 55 mm
Viscat softening temperature: ±90 °C

form

solid (Filament)

hardness

45D (, Shore D Hardness)

color

red

Looking for similar products? Visit Product Comparison Guide

General description

Flexible Thermoplastic Copolyester (TPC) Printing Filament is a rubber-like 3D printer filament with a Shore hardness of 45D that allows for the printing of flexible objects. This flexible filament will not deform or break when stressed by bending (Charpy notched impact strength test) and has shown ″flexural memory″ which allows materials to return to their original shape after being bent, dented, or folded. In addition to its high flexibility, this filament features many additional beneficial properties such as high temperature resistance, good chemical resistance, high strength, and excellent UV resistance. Due to its ester linkages, this filament is degradable by hydrolysis and is made partially from renewable carbon content (e.g. bio-based oils). When not in use, the filament should be stored at room temperature in dry conditions, such as in a sealed plastic bag or in a closed container with desiccant. Recommended initial printer settings can be found in the ′General Print Settings′ file.

Application

Flexible thermoplastic copolyester (TPC) printing filament is a polyester-based material with properties similar to polyurethane-based (TPU) filaments. Due to their flexibility and stability, TPU has been used to synthesize nanoparticles for cartilage tissue engineering, peripheral nerve conduits, and tracheal scaffolds. Due to its ester linkages, thermoplastic copolyesters are able to undergo hydrolytic degradation more readily than polyurethanes, making them more suitable for biomedical applications. Cabrera et al. used thermoplastic copolyesters to print self-expandable polymer stents that can be implanted in a minimally invasive manner. These rapidly prototyped structures were shown to have properties similar to that of nitinol-based stents and to degrade via hydrolysis. Based upon these ideal properties, thermoplastic copolyester filaments have great potential in additional bioengineering applications.

Legal Information

Product of Formfutura VOF

FlexiFil is a trademark of Formfutura VOF
FlexiFil is a trademark of Formfutura VOF

Storage Class

11 - Combustible Solids

wgk_germany

WGK 3

flash_point_f

Not applicable

flash_point_c

Not applicable


Certificates of Analysis (COA)

Search for Certificates of Analysis (COA) by entering the products Lot/Batch Number. Lot and Batch Numbers can be found on a product’s label following the words ‘Lot’ or ‘Batch’.

Already Own This Product?

Find documentation for the products that you have recently purchased in the Document Library.

Visit the Document Library

Computationally Designed 3D Printed Self-Expandable Polymer Stents with Biodegradation Capacity for Minimally Invasive Heart Valve Implantation: A Proof-of-Concept Study
Cabrera, M.S. et al.
3D printing and additive manufacturing, 4(1), 19-29 (2017)
Novel flexible nerve conduits made of water-based biodegradable polyurethane for peripheral nerve regeneration
Hsu, S.-H. et al.
Journal of Biomedical Materials Research Part A, 105A, 1383-1392 (2017)
3D printed polyurethane prosthesis for partial tracheal reconstruction: a pilot animal study
Jung, S.Y. et al.
Biofabrication, 8(4), 045015 -045015 (2016)
Biomedical applications of biodegradable polymers
Ulery, B.D. et al.
Journal of Polymer Science. Part B, Polymer Physics, 49(12), 832-864 (2011)
Synthesis and 3D printing of biodegradable polyurethane elastomer by a water-based process for cartilage tissue engineering applications.
Hung, et al.
Advanced Helathcare Materials, 3(10), 1578-1587 (2014)

Our team of scientists has experience in all areas of research including Life Science, Material Science, Chemical Synthesis, Chromatography, Analytical and many others.

Contact Technical Service