We are currently collaborating with a team from TU Vienna’s Institute for Structural Design and Timber Engineering (project leader Baris Cokcan) towards realizing a wooden pavilion structure for an upcoming exhibition.
Recently, a team from the Robotic Woodcraft project attended the conference on Advancing Wood Architecture, hosted by Achim Menges of the University of Stuttgart.
As part of the European Robotics Forum that took place this week in Vienna, the Robotic Woodcraft project and the University of Applied Arts Vienna offered a LabVisit that took place on the evening before the conference-kickoff.
ERF participants could visit the Austrian Institute of Technology, the RoboLab at FHTW and the Robotic Woodcraft lab.
On December 11th, 2014, the Robotic Woodcraft team is inviting all interested staff and students of the University for Applied Arts, as well as external participants, to attend a compact robot presentation at the Department of Wood Technology. The goal of this demonstration is to showcase the new and exciting possibilities that a large robotic arm offers to creative users. Several current and past Robotic-Woodcraft projects will be presented to inspire attendees to think of new possibilities how robots can enable and inform new, creative applications. To register, please send an eMail to email@example.com
10:00-10:45: Robot presentation and demonstration
10:45-11:15: Presentation of realized projects
11:15-12:15: Robot programming with Grasshopper and
Rhino via KUKA|prc (optional)
As part of a press conference at the University for Applied Arts, the head of the university, Dr. Gerald Bast, led the assembled journalists to the Department of Wood Technology to showcase the newly acquired KUKA robotic arm. The Robotic Woodcraft team presented him with his likeness cut into laminated wood, realized through a custom-developed parametric design script.
At the end of May, KUKA delivered a brand-new KUKA KR120 R2500 Quantec in RAL9002 “grey-white” to the Robotic Woodcraft project at the University for Applied Arts Vienna. The project has greatly evolved from its humble beginnings when the robot was standing lonely in a corner of the wood-construction workshop. Since then, a huge amount of knowledge has been transferred from the wood-experts to the robot-experts and the other way around, with highly engaged students now already realizing parts of their diploma thesis using the robot’s multi-axis milling capabilities.
As part of an inter-universitary cooperation, Robotic Woodcraft supported the robotic fabrication of the “Addition” wood pavilion. Designed by students of TU Vienna’s Institute for Timber Construction (Prof. Winter) under the guidance of Baris Cokcan, the pavilion was to be built in a extremely short timeframe in order to be ready in time for an exhibition at the AZW architecture center, located in Vienna’s famous Museumsquartier.
One of the main challenges was the multi-axis milling over several hundred knots at a low budget. After generating the robot code using Grasshopper and the Association for Robots in Architecture’s software KUKA|prc (parametric robot control), two KR16s worked in tandem to precisely mill the wooden elements.
Just in time for the semester break our milling spindle has arrived! While the setup took us some time – in the age of 50EUR smartphones, configuring an expensive inverter via four buttons and a 5-digit display is… frustrating – we were still done faster than anticipated and had the chance to mill a first piece. Fellow robot enthusiast Philipp quickly designed a surface in Rhino that we then prepared for fabrication via SprutCAM and KUKA|prc. And while the final result may not be perfect yet, it turned out really fine for a first day with only very loosely calibrated tools and workflows that haven’t yet been finely tuned.
Thanks go out to Tom for providing electro-technical know-how, Philipp for the ultra-quick design, and of course to our student assistants Sebastian and Georg.
The safety regulations mentioned in the previous post are sufficiently complex that we decided to call the professionals, in our case Pilz. They’re market leaders in safety equipment and are now installing everything that is required to make a robot safe to use. Starting with a safety fence that is equipped with “bullet-proof” 8mm thick polycarbonate (less to protect “against” the robot, but rather to keep damaged rotating tools and chipped material within the cell), sensors that detect when a door is closed and when it’s open, and electronic locks to keep users out when the robot is operating in Auto mode. All of this is wired to a safety-PLC which is actually housed within the KUKA robot cabinet. Behind the fence are Christoph Ryll, David Machanek, and Mr. Paradeis of Pilz who developed and implemented our robot-safety concept.