cyborg skull - 3D experimental prototype

The head cyborg prototype presented here is an experimental work, designed for human-machine interaction.

Link: https://youtu.be/TnqsjWtvDhA

This head, or more precisely its segmented skull, represents the culmination of intense research in the field of cybernetics and advanced robotics. Here's a detailed look at its impressive components and features:

Segmented Skull: The skull structure is divided into several parts, offering exceptional modularity for easy assembly and customization. This innovative design enables seamless integration of internal and external components, while guaranteeing optimum robustness and structural stability.

Virtual Brain: At the heart of this prototype lies a revolutionary virtual brain system. Housed in a specially designed cage, this virtual brain offers an adaptable platform for a multitude of applications. Whether for advanced data processing, autonomous decision-making or artificial intelligence simulation, this virtual brain opens up new perspectives in the field of cybernetics.

Attachment system: The skull cage is equipped with attachment points for various devices, such as electrodes for neural signal capture or cameras for advanced visual perception. This versatility offers unrivalled flexibility in configuring the cyborg to the specific needs of each project.

Artificial Cyber Eyes: To complete its sensory arsenal, this cyborg is equipped with a pair of artificial cyber eyes. Featuring cutting-edge computer vision technology, these eyes enable high-resolution visual perception and advanced object recognition, essential for complex navigation tasks and interaction with the environment.

Printable manufacturing: All parts of this prototype are designed to be printable, offering unprecedented accessibility and adaptability in the manufacture and assembly of support robots, also known as "botcamp". This approach democratizes access to cutting-edge technology, enabling robotics professionals and discerning hobbyists alike to explore new frontiers in cyber robotics.

Assembly and Programming: Although this project offers infinite possibilities, its assembly and programming require advanced expertise in programming and cyber robotics. Those interested in building this prototype should have a solid grounding in these fields to exploit its full potential.

Aimed at robotics professionals and knowledgeable amateurs alike, this project opens up exciting new possibilities in the creation of support robots and beyond.

Material: PLA, ABS, PETG (or any other material compatible with your 3D printer)

Layer thickness: 0.2 mm - 0.3 mm (for a balance between print quality and speed)

Filling: Between 20% and 40% to ensure good strength while saving material

Extrusion temperature: According to your filament manufacturer's recommendations, generally between 200°C and 220°C for PLA, for example.

Print speed: Between 40 mm/s and 60 mm/s for stable, accurate printing.

Supports: Depending on the parts of the model that need them, usually activated for large overhangs

Brim or Raft: Optional, but can help adhere the model to the print platform, especially for large parts or parts prone to delamination

For laser or CNC cutting, the parameters will depend on the material you're using as well as the power of your machine. Here are some basic parameters:

Material: Acrylic, wood, plastic, etc.

Cutting/engraving thickness: Depends on material and specific application, but generally between 1 mm and 6 mm for cutting and between 0.1 mm and 2 mm for engraving.

Cutting/engraving speed: Adjustable according to the power of your machine and the material used, generally between 10 mm/s and 100 mm/s for cutting and between 300 mm/s and 1000 mm/s for engraving.

Laser power : Depends on material and cutting/engraving thickness, usually between 20% and 100% of your machine's maximum power, but this can vary.

Laser frequency: Generally between 5000 Hz and 20000 Hz, but this can vary depending on the machine and material.

Make sure you always carry out preliminary tests to find the optimum settings for your 3D printing or laser/CNC cutting configuration, and take into account the specific recommendations for your machine and material.