Difference between revisions of "2019W2:Page4"
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Two D2RP studies are proposed: <br> | Two D2RP studies are proposed: <br> | ||
| − | 1. Subtractive D2RP: The development of a structurally optimized wall/ceiling/floor component milled from EPS , <br> | + | 1. Subtractive D2RP: The development of a structurally optimized wall/ceiling/floor component milled from EPS, <br> |
| − | 2. Additive D2RP: The development of a 3D printed acoustically optimized layer on top of the milled wall/ceiling/floor component | + | 2. Additive D2RP: The development of a 3D printed acoustically optimized layer on top of the milled wall/ceiling/floor component. <br> |
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Revision as of 20:11, 16 March 2020
ONLINE CONTENT & APPROACH
This online workshop introduces students to computational design strategies for Design-to-Robotic-Production (D2RP) in order to achieve material and process efficiency. Students are asked to identify aspects related to robotic production that are relevant for the Off-Earth Habitat project and map those onto the proposed schematic designs. The exercise focuses on hybrid componentiality, which implies that components of various materials and properties are interconnected to establish together a multi-performative whole.
Two D2RP studies are proposed:
1. Subtractive D2RP: The development of a structurally optimized wall/ceiling/floor component milled from EPS,
2. Additive D2RP: The development of a 3D printed acoustically optimized layer on top of the milled wall/ceiling/floor component.
