Flexible 3D Printing Filaments: Difference between revisions
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=List= | =List= | ||
==TPU== | ==TPU== | ||
* | *[[TPU]] | ||
==Natural Rubber== | |||
*Supposedly vulcanized can't melt | |||
*NEEDS MORE RESEARCH | |||
*[https://pubs.acs.org/doi/abs/10.1021/ja01490a020 A Whitepaper on The Melting Point of Natural Rubber] | |||
*Probably wouldn't be an off the shelf option, but perhaps [[Rubber From Dandelions]] or something, although the complexity may be more trouble than it's worth | |||
*Also would most likely require vulcanization | |||
*May also require the addition of [[Carbon Black]] | |||
= | =Internal Links= | ||
*[[Flexion]] | *[[Flexion]] | ||
= | =External Links= | ||
* | * | ||
[[Category: Plastics]] | |||
Latest revision as of 19:53, 15 July 2020
Basics
- Plastic filaments which flex upon application of force
- Good for many unique uses such as joints
- Can be problematic however as they can clog and jam extruders, and they print strangly (ie stringing etc)
Units of Meaure
List
TPU
Natural Rubber
- Supposedly vulcanized can't melt
- NEEDS MORE RESEARCH
- A Whitepaper on The Melting Point of Natural Rubber
- Probably wouldn't be an off the shelf option, but perhaps Rubber From Dandelions or something, although the complexity may be more trouble than it's worth
- Also would most likely require vulcanization
- May also require the addition of Carbon Black