About my blog
New depth sensors such as the one embedded in the MS Kinect system work in real-time, enabling to create an instant 3D scan of objects. In this project, we are exploring a large-scale installation that demonstrates this by a 400+ array of motors and LEDS. This work includes interaction design, hard-coding and lots of soldering etc. The result will be put on exhibit on various international shows.(Expert: Jouke Verlinden)
- onbekend (14)
Posts by Mauricio Sandoval Martínez
We all chose this minor because we like to build
things or want to learn more about how to build things and that’s exactly what
we did at this assignment. We were lucky
we had a good team, everyone had different skills and we could fill each other
gaps and necessities. From the start we
could easily understand each other and make a good planning for the project. After
the first week we have analysed the problem we divided the work, but in the end
we can say that everyone did a bit of
everything. From the start we knew we
will get busy creating the frame for a big scale kinetic mirror of 400 pixels
and also make a better version of light diffusers. That was it. It would have
been nice if we also learned some more about the programming as well. We thought
that we could do some research with the software and mechanics of the actual
prototype of 16 pixels but we were just too busy building frame prototypes. The
process was very simple, we start with making a program of requirements
(forces, weights, design) than conceptualisation and finally making a
prototype. We could not get to building the real one but were not ready to make
it either. We learned while making the frame mock-ups that always something
goes wrong and that we have to do a lot of trial and error mistakes to get
nearly to something that looks like your design. In this project we learned to use new
machines like the thermoforming machine.
this was a fun and instructive project to do. We were able to actually face
real-life problems and bring our imagination to the real world making something
that will be used international. We are
very pleased with our learning’s and achievements during this project and hoop
to have the chance to build the real frame in a near future.
Here is a render of our final Frame concept
Before we came with this design we had a pipe like frame, but becouse our scharp angles was very difficult to make.
As team we had to make hard choices while designing, trying to acchive a light weight, strong and easy to build frame design.
The past week we’ve been working on a lot of aspects of the frame, firstly we made a more detailed mock-up of the 400 pixels:
Did some impact tests to see what the worst-case scenario would be:
Worst case scenario: if everything goes wrong and all the 400 pixels receive power without the control of microchips we are looking at a maximum force of 2 kN. Next step was to take the previously posted frame mockup and run it through some simulations:
Calculations made in conjunction with Rob Luxen has shown us that we’ll be needing at least three computer power supplies. Below are some images of the ones we’ve chosen:
the cheapest and best way to do this was with thermoforming process. Then
by a lot of trial and error experiments with thickness and types of plastics we
came out with the solution: "vikureen plaat" of 1 mm thickness.
Here is a 3D concept of the way we want to make and connect the LD’s:
We make a real study of how the light duffused with this LD:
Now the BIG CHALLENGE is to make 400 LD’s. We will try to do 100 times 4 LD, because the
method to have a non-folded diffuser requires precision and 2 people.