3D Printed Robotic Arm: Difference between revisions
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=Basics= | =Basics= | ||
* | *A [[Robotic Arm]] which has most of it's componets [[3D Printer | 3D Printed]] | ||
*Reduces cost (ie no metal cutting needed), at the price of some small structual strength/enviromental hardening | |||
*Great for prototyping, development, and indoor small-medium load use | |||
=Team Germany= | =Team Germany= | ||
Revision as of 16:52, 8 August 2020
Basics
- A Robotic Arm which has most of it's componets 3D Printed
- Reduces cost (ie no metal cutting needed), at the price of some small structual strength/enviromental hardening
- Great for prototyping, development, and indoor small-medium load use
Team Germany
https://hackaday.io/project/3800-3d-printable-robot-arm
Team Switzerland
- Good one - RAMPS controlled. Need to program it via code.
- No feedback.
- Practical use case - if we can create software to generate toolpaths, this would be a practical welding robot when scaled up.
- Easy concept - 6 degrees of freedom, + 6 stepper drivers. Scalable - as drivers can be whatever size required.
- Great project for open source TB6600, open source Arduinos, 3D printing, 3d printed belts and bearings for larger size machines.
Download all files, GPLv3, from here:
git clone https://github.com/SkyentificGit/SmallRobotArm
Scalability
- Mechanically, this can be scaled up to whatever size stepper motor is available. with proper geometry, allowed forces can be large.
- Basics: if we have a 50lb force with a 1/2" pulley and 15mm GT2 belt - we can get to 500 lb pull readily on a 5" pulley! Good forces are allowed. We can probably get 5 kg load on the end effector for an industrial welding robot.