Showing posts with label strength. Show all posts
Showing posts with label strength. Show all posts
Jan 26, 2020
Mar 30, 2019
How Strong are 3D Printed Thread Inserts?
Great exploratory video by CNC Kitchen about strenght of 3d printed thread inserts.
Sep 23, 2017
Angus And His Experiance With 3D Printed Combat Robot Parts
Angus from Maker's Muse shares his knowledge and experience with a DIY battle robot he created. Since it uses a lot of 3d printed parts it is interesting to see how they cope in this type of application. The robot is named "Vanguard", and it's a 30lb of pure machine aggression :-)
Dec 11, 2016
Bake your PLA 3D prints in an oven for a higher strength
Thomas made an interesting experiment where he baked in an standard household oven some PLA (and other filament) objects. It looks like you can improve the strength significantly with this simple method.
See the entire process and measurements in his video:
With change in strength, there is naturally some shrinkage and expansion in different axis.
Let us know in the comments if you have simillar experiences with heat treated PLA or simillar materials!
See the entire process and measurements in his video:
With change in strength, there is naturally some shrinkage and expansion in different axis.
Let us know in the comments if you have simillar experiences with heat treated PLA or simillar materials!
Dec 17, 2014
E3D Volcano super high flow nozzle upgrade will speed up your 3d printing
E3D just released their Volcano super high flow nozzle upgrade that will speed up your 3d printing by pushing more filament trough the hot end.
Putting on a larger diameter nozzle and extruding more molten filament also improves strength since the more mass and more heat improve adhesion between the layers.
Volcano product home page:
http://e3d-online.com/index.php?route=extras/blog/getblog&blog_id=28
Here is a video demonstration and presentation of Volcano:
Here is a picture of Volcano heater block and various diameter larger nozzles:
Putting on a larger diameter nozzle and extruding more molten filament also improves strength since the more mass and more heat improve adhesion between the layers.
Volcano product home page:
http://e3d-online.com/index.php?route=extras/blog/getblog&blog_id=28
Here is a video demonstration and presentation of Volcano:
Here is a picture of Volcano heater block and various diameter larger nozzles:
Apr 5, 2014
Michigan Tech study on tensile strength of models printed on RepRaps and commercial 3d printers
They found out that the objects can have the same tensile strength.
They used this model for tensile strength testing:
http://www.thingiverse.com/thing:28987
Study page on Appropedia with more details:
http://www.appropedia.org/Mechanical_Properties_of_Components_Fabricated_with_Open-Source_3-D_Printers_Under_Realistic_Environmental_Conditions
Study on Academia.org:
https://www.academia.edu/6209168/Mechanical_properties_of_components_fabricated_with_open-source_3-D_printers_under_realistic_environmental_conditions
Study abstract
The recent development of the RepRap, an open-source self-replicating rapid prototyper, has made 3-D polymer-based printers readily available to the public at low costs (<$500). The resultant uptake of 3-D printing technology enables for the first time mass-scale distributed digital manufacturing. RepRap variants currently fabricate objects primarily from acrylonitrile butadiene styrene (ABS) and polylactic acid (PLA), which have melting temperatures low enough to use in melt extrusion outside of a dedicated facility, while high enough for prints to retain their shape at average use temperatures. In order for RepRap printed parts to be useful for engineering applications the mechanical properties of printed parts must be known. This study quantifies the basic tensile strength and elastic modulus of printed components using realistic environmental conditions for standard users of a selection of open-source 3-D printers. The results find average tensile strengths of 28.5 MPa for ABS and 56.6 MPa for PLA with average elastic moduli of 1807 MPa for ABS and 3368 MPa for PLA. It is clear from these results that parts printed from tuned, low-cost, open-source RepRap 3-D printers can be considered as mechanically functional in tensile applications as those from commercial vendors.
Study highlights
- Low costs enable mass-scale distributed digital manufacturing in ABS, PLA.
- Average tensile strengths of 28.5 MPa for ABS and 56.6 MPa for PLA.
- Average elastic moduli of 1807 MPA for ABS and 3368 MPa for PLA.
- RepRaps are as mechanically functional as commercial 3-D printers
They used this model for tensile strength testing:
http://www.thingiverse.com/thing:28987
Study page on Appropedia with more details:
http://www.appropedia.org/Mechanical_Properties_of_Components_Fabricated_with_Open-Source_3-D_Printers_Under_Realistic_Environmental_Conditions
Study on Academia.org:
https://www.academia.edu/6209168/Mechanical_properties_of_components_fabricated_with_open-source_3-D_printers_under_realistic_environmental_conditions
Sep 27, 2013
Strength test of 3d printed ABS part
It is done by high precision scientific method "press-it-until-brakes" ...
Video by: http://www.youtube.com/user/radusava?feature=watch
How strong are your 3d printed parts? ( Btw: will they blend? :-))))))) )
Video by: http://www.youtube.com/user/radusava?feature=watch
How strong are your 3d printed parts? ( Btw: will they blend? :-))))))) )
Subscribe to:
Posts (Atom)