Livestream-Interactive Confetti Cannon

Add Patterned Skins to 3D Prints with Hydro Dipping

Making Custom Lapel Pins on a Milling Machine

Keep Everyones Backpacks Off the Floor with this Sturdy Hanger

Maker Pro News: Lessons From CES, Speech Recognition for Kids, and the Humble Mastermind of Roku

Tips of the Week: Soldering 101, Soap Case Project Boxes, Flexi-Tips for Gluing

In the past few years, a flurry of new materials has hit the desktop 3D-printing market, enabling makers to do much more with their machines. We now have dissolvable support materials, plastics that simulate wood, stone, and metal, and even the start of conductive filaments. Flexible materials are another popular option, enabling stretchy, bendy, and rubber-like creations. As with all filaments, there are many different manufacturers and variations. Heres what it takes to get printing with flexible filaments.

The primary requirement for printing with flexibles is an extruder with a direct path that keeps the filament firmly in place from the time it leaves the drive gear until it enters the barrel of the hot end. This type of setup can be seen on the Printrbot Alu Extruder, which has a metal guide after the drive gear to pass the filament directly into the heater barrel.

Most extruders have been designed for use with stiff filaments that are pushed through the hot end by placing pressure on the filament itself. This is problematic with flexible filaments, because their elastic nature makes it difficult to create the backpressure needed for extrusion.

Many extruders can be upgraded with parts found on YouMagine and Thingiverse that will allow you to print using your existing setup. In addition, LulzBot has created their own swappable Flexystruder.

To help reduce the pressure required to push pliable filament through your hot end, it helps to run your extruder a little hot. Although vendors suggested print temperatures vary, I tend to lean towards the higher numbers. Increased temperature makes the materials more liquid-like, allowing them to flow more easily through the nozzle. The downside is that the materials tend to ooze more when traveling. To solve this, increase the retraction distance in your slicer settings.

Finally, make sure you print slowly (around 30mm/s). Printing fast can cause pressure to build up in your extruder. Flexible prints can also easily bend out of the way when a rapidly moving extruder passes by them, causing errors and poor print quality.

We tested four filaments that cover a great range of flex properties. The materials tested were, from left to right: Zen Toolworks Flexible Filament, NinjaFlex, Filaflex, and Flex EcoPLA.

To better understand what flexible means in each case, we printed identical test objects using each filament, then conducted two experiments to measure different aspects of flex.

A cylinder measuring 20mm in diameter and 50mm tall was printed with two shells and a 10% infill. These were each placed in a sample holder attached on one side to a beam and on the other side to a scale and a weight. A bucket (acting as the weight) was slowly filled with water to increase the load until the print buckled and was crushed. Those weights were then recorded and the process was repeated to ensure accuracy.

In this test a dog bone was printed with a 30mm5mm5mm center section. Each dog bone was loaded into a holder and a fixed weight of either 10kg or 4kg was placed onto the bottom holder to stretch the sample piece. After the weight was applied, the distance stretched was measured and the percentage stretched was calculated.

In the stretch test, both NinjaFlex and Filaflex stretched our test rig beyond its capabilities with 10kg, making them perfect choices for when you want super squishy and stretchy items.

The new Zen Toolworks filament and FlexPLA are great for printing objects that are bendable, but not very stretchy (such as timing belts).

While NinjaFlex seems to be the most popular currently (and adds some fun features, like being able to bond to PLA and ABS), all four of these materials could be useful to the resourceful tinkerer.

Matt is a community organizer and founder of 3DPPVD, Ocean State Maker Mill, and HackPittsburgh. He is Makes digital fabrication and reviews editor.

What printer did you use now? Did you use Printrbot Alu Extruder? We do look for a printer that suits ninjaflex or filaflex since we need the most flexy and rubberlike material.

what printer did you use for these filaments?

Thanks for the informative post! We referenced some of your findings in our blog post on how to get best results with flexible filament here feel free to share through your channels if you think this would be useful for your followers or let us know if we missed anything important! Thanks

Nice test, just what I was hoping to find.

How come the EcoFlex stretches more with 4kg load than with 10kg? Did you swap the numbers?

Send us feedback on our site design, bugs, story ideas, maker community events and any other share-worthy thoughts.

We cant guarantee a response to each submission, but we promise to think about every one.

Stay inspired with the Make: newsletter

Stay inspired with the Make: newsletter

Make: and Maker Faire are registered trademarks of Maker Media, Inc.

Copyright © 2004-2018 Maker Media, Inc. All rights reserved

you are now signed up to the Make: newsletter.

The latest news about startups, products, incubators, and innovators

Keep up with the Greatest Show(and tell) on Earth

Thanks for signing up. Please check your email to confirm.

Your FREE PDF is on its way. Please check your email. You will also be receiving the weekly Make: Newsletter to keep you inspired with new projects and more product reviews.

Your changes have been saved. Keep Making!

Thanks for your submission. Our editors will review your materials and follow up with you via email as soon as possible. In the meantime, keep making stuff!

Make: is the voice of the Maker Movement, empowering, inspiring, and connecting Makers worldwide to tinker and hack. Subscribe to Make Magazine Today!