Category Archives: Aron Biro

3D-Slidate(Slide-Rotate)


We wanted to create a set of joints that would allow our structure to expand and shrink, move in every axis and in the same time be able to connect with another module so it can be populated and create a dynamic surface. The geometry we used is based on two hexagons, one nested into the other connected only in three points. The inside hexagon can vary the length of its sides and the angles between them while moving in every direction when the outside can only vary the angles between the sides. The assembly can be tiled in two dimensions and can possibly create a lightning system or a performing façade.


1st joint –Characteritics -1 connection that permits sliding on a bar, 1 connection that permit 3-axis rotation
Geometry –One internal sphere with a hole for sliding and one external ring with a joint that car slide on the sphere offering 3-axis rotation(restricted by the bar that slides on the sphere)
Functionality – forms the internal part of our structure and allows movement to every direction

2nd joint -Characteritics -1 connection that permits sliding on a bar, 2 connections that permit 3-axis rotation
Geometry – One internal sphere with a hole for sliding and two external rings with joints that can slide on the sphere offering 3-axis rotation(restricted by the bar that slides on the sphere and the interaction between this two rings)
Functionality – forms the external part of our structure and allows movement to every direction

3rd joint –Characteritics -4 connections that permit two axis rotation
Geometry – Four different layers of half rings that can rotate about a central axis. On each ring there is a joint that can move along its length
Functionality – forms the external part of our structure and allows movement to every direction

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MILLING: CONTRAST


In this milling exercise we tried to create a panel that would show the contradiction between a smooth surface and a more machine made- industrial set of drilled points. We used a surface as the starting point and on it we traced a set of irregular curves that went through only the first layer of our valcromat panel. For this first strategy we selected the 54mm ball mill in order to produce a rather smooth surface at the boundaries of our curves. Moving on we selected a second set of surfaces and from these we produced points that we then used for our second strategy. This time we used the 10mm flat mill and we tried to go through the second layer of the material to bring out the contradiction of the techniques even more.


1st Strategy – Engraving on curves – Tool : 54 Ballmill – Duration : 45 minutes
2nd Strategy – Engraving on points – Tool : 10 Flatmill – Duration : 20 minutes

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PLEXI_CUBE


PLEXI_CUBE

In this project we were working with plexiglass (methacrylate) and we focused on creating a lamp using the technique of ribbing.

We decided to explore the possible different connections between the elements of our lamp and keep the form relatively simple, having the external volume of a cube as abounding box and in its center a sphere that will provide the necessary space for the lamp. The general idea was to increase the complexity of the ribbing technique, using more than two different axises for the planar sections. In the process we realized the bending and breaking limitations of the material and the effect topology of objects has in contouring-ribbing objects.

Cutting surface = 5400 cm2 Material used = 3787,3 cm Waste Material = 1612,7 cm2 (29,86 %)

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