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__NOTITLE__ __NOTOC__
  
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'''[[project12:Group1| Group 1]]''' &nbsp; '''[[project12:Group2| Group 2]]''' &nbsp; '''[[project12:Group3| Group 3]]'''
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</div>
  
=='''MUlTI-MATERIAL ASSEMBLY (MA) '''==
+
=='''MUlTI-MATERIAL ASSEMBLY (MA) '''==  
  
Keywords
+
<div align="justify">
 +
<i>Keywords</i><br>
 
Multi-materiality, Assembly, Material Computation, Production Computation, MultiMode Robotic Production, Hybrid Properties, Material Gradients
 
Multi-materiality, Assembly, Material Computation, Production Computation, MultiMode Robotic Production, Hybrid Properties, Material Gradients
 +
</div>
  
 
=='''CONTEXT '''==
 
=='''CONTEXT '''==
Advancement in design computation and robotic production is leading to novel methods of material fusion on multiple scales. In architectural design, systematic methods of computing, modeling, simulating and representing multi-materiality and assembly are required. Furthermore, hacking and modifying production methods are leading to efficient and meaningful materialization processes. In this context, the workshop on Multi-material Assembly (MA) aims to explore and establish computational design to programmable production and assembly processes.  
+
 
 +
<div align="justify">
 +
Advancement in design computation and robotic production is leading to novel methods of material fusion on multiple scales. In architectural design, systematic methods of computing, modeling, simulating and representing multi-materiality and assembly are required. Furthermore, hacking and modifying production methods are leading to efficient and meaningful materialization processes. In this context, the workshop on Multi-material Assembly (MA) aims to explore and establish computational design to programmable production and assembly processes.
 +
</div>
  
 
=='''OBJECTIVE & FOCUS '''==
 
=='''OBJECTIVE & FOCUS '''==
The focus of this workshop is at the intersection of multi-materiality and assembly of multi-material components. The objective is to exploit informed multi-material D2RP&O approaches. Informed in this context mainly refers to structural, functional and environmental parametres. Therefore in each project one or multiple parameters will be chosen to inform the design. Modeling and production of multi-materiality as well as assembly requires integration of physical computing with materialization sequences. For instance, customized toolpath or G-code generation methods, voxel based representation of materiality, Finite Element Methods (FEM) of  structural simulation, etc. Furthermore, informed assembly allows for growing larger than the size of allowed by the production setup. This entails a comprehensive understanding of structural modeling ranging from fundamental structural design concepts like degrees of freedom in multiple direction to multi-materiality itself that may improve the local or global stability and coherence of the assembly.  
+
 
 +
<div align="justify">
 +
The focus of this workshop is at the intersection of multi-materiality and assembly of multi-material components. The objective is to exploit informed multi-material D2RP&O approaches. Informed in this context mainly refers to structural, functional and environmental parametres. Therefore in each project one or multiple parameters will be chosen to inform the design. Modeling and production of multi-materiality as well as assembly requires integration of physical computing with materialization sequences. For instance, customized toolpath or G-code generation methods, voxel based representation of materiality, Finite Element Methods (FEM) of  structural simulation, etc. Furthermore, informed assembly allows for growing larger than the size of allowed by the production setup. This entails a comprehensive understanding of structural modeling ranging from fundamental structural design concepts like degrees of freedom in multiple direction to multi-materiality itself that may improve the local or global stability and coherence of the assembly.
 +
</div>
  
 
=='''WORKSHOP STRUCTURE '''==
 
=='''WORKSHOP STRUCTURE '''==
During the MA workshop, students will work in groups and will explore 3 main aspects of assembly:
 
Group 1: Porous-solid interlocking systems
 
Group 2: Soft-rigid intertwining systems
 
Group 3: Physical-digital interweaving with existing topologies
 
  
==''' DESIGN, WORKING PACKAGES & DELIVERABLES'''==  
+
<div align="justify">
The initial input topology to this workshop will be a section part of previously designed stage-pavilion titled Echosphere (http://gsm.hyperbody.nl/index.php/Msc2G3:Group) and/or MSc 2 prototypes from previous MSc 2. This initial input is only a departure point, which during the workshop may differentiate depending on the focus of each group.  
+
During the MA workshop, students will work in groups and will explore 3 main aspects of assembly:<br><br>
The key working packages of this workshop are divided into two main categories. First category refers to computational design  methods of multi-materiality and assembly. The second emphasises the bridging of digital design approaches with physical programmable systems like 3D printers and robotic arms. Respective feedback loops shall be used as inputs that inform the design in terms of materialization.  
+
<i>Group 1:</i> <b>Porous-solid interlocking systems</b><br>
 +
<i>Group 2:</i> <b>Soft-rigid intertwining systems</b><br>
 +
<i>Group 3:</i> <b>Physical-digital interweaving with existing topologies</b>
 +
</div>
 +
 
 +
==''' DESIGN, WORK PACKAGES & DELIVERABLES'''==
 +
 
 +
<div align="justify">
 +
The initial input topology to this workshop will be a section part of previously designed stage-pavilion titled Echosphere (http://gsm.hyperbody.nl/index.php/Msc2G3:Group) and/or MSc 2 prototypes from previous MSc 2. This initial input is only a departure point, which during the workshop may differentiate depending on the focus of each group.<br>
 +
The key working packages of this workshop are divided into two main categories. First category refers to computational design  methods of multi-materiality and assembly. The second emphasises the bridging of digital design approaches with physical programmable systems like 3D printers and robotic arms. Respective feedback loops shall be used as inputs that inform the design in terms of materialization.<br>
 
The workshop deliverables include design computation methodologies. These computational models includes systemic representation of workflows and data exchange between multiple plugins and sub-algorithms as well as interoperability between digital and physical modules. Each group may deliver specific customized methods of material properties and behaviour simulations implemented in the design process. Moreover a flowchart diagram of process as well as a short video of design to production experiments and prototyping are considered as key deliverables of this workshop. Physical prototyping of the the design is not obligatory in the prototyping planning session. Each group in dialog with tutors will decide upon either physical prototyping or proof of concept documentation of the process. Production methods available in this workshop will be 3D printing with an ultimaker 2 and a KUKA robotic arm.
 
The workshop deliverables include design computation methodologies. These computational models includes systemic representation of workflows and data exchange between multiple plugins and sub-algorithms as well as interoperability between digital and physical modules. Each group may deliver specific customized methods of material properties and behaviour simulations implemented in the design process. Moreover a flowchart diagram of process as well as a short video of design to production experiments and prototyping are considered as key deliverables of this workshop. Physical prototyping of the the design is not obligatory in the prototyping planning session. Each group in dialog with tutors will decide upon either physical prototyping or proof of concept documentation of the process. Production methods available in this workshop will be 3D printing with an ultimaker 2 and a KUKA robotic arm.
 +
</div>
  
 
=='''SCHEDULE '''==  
 
=='''SCHEDULE '''==  
Monday 25/9
+
 
Introduction _ Set the groups
+
<div align="justify">
Design brainstorming sessions
+
<i>Monday 25/9</i><br>
Hackathons and hands of computation  
+
- Introduction _ Set the groups<br>
Tuesday 26/9
+
- Design brainstorming sessions<br>
Design sessions
+
- Hackathons and hands of computation<br><br>
Hackathons
+
<i>Tuesday 26/9</i><br>
Prototyping planning  
+
- Design sessions<br>
Wednesday 27/9
+
- Hackathons<br>
Design sessions
+
- Prototyping planning<br><br>
Hackatons
+
<i>Wednesday 27/9</i><br>
Prototyping and documentation
+
- Design sessions<br>
Thursday 28/9  
+
- Hackatons<br>
Design development  
+
- Prototyping and documentation<br><br>
Prototyping and or proof of concept
+
<i>Thursday 28/9</i><br>
Friday 29/9
+
- Design development<br>
Presentation  
+
- Prototyping and or proof of concept<br><br>
Finetuning
+
<i>Friday 29/9</i><br>
Monday 2/10
+
- Presentation<br>
Prototypes and/or documentation of D2RP processes  
+
- Finetuning<br><br>
Final presentation and report
+
<i>Monday 2/10</i><br>
 +
- Prototypes and/or documentation of D2RP processes<br>
 +
- Final presentation and report<br>
 +
</div>
  
 
=='''SOFTWARE & METHODS '''==  
 
=='''SOFTWARE & METHODS '''==  
Rhino / Grasshopper
 
Grasshopper plugins:
 
Kangaroo (physical + interactive simulations)
 
http://www.food4rhino.com/app/kangaroo-physics
 
Karamba (structural optimization)
 
http://www.food4rhino.com/app/karamba
 
Millipede (topological optimization)
 
http://www.sawapan.eu/
 
Silkworm (3D printing/G-Code creation)
 
http://www.food4rhino.com/app/silkworm
 
Kuka PRC (robotic control)
 
http://www.food4rhino.com/app/kukaprc-parametric-robot-control-grasshopper
 
Ladybug Tools (environmental analysis and more)
 
http://www.food4rhino.com/app/ladybug-tools
 
3DF Zephyr (3D scanning with videos)
 
https://www.3dflow.net/3df-zephyr-pro-3d-models-from-photos/
 
Realflow (material simulation)
 
https://www.nextlimit.com/realflow/
 
  
=='''Coordinators & Tutors'''==  
+
<div align="justify">
Henriette Bier, Sina Mostafavi, and Benjamin Kemper
+
<b>Computation</b><br>
 +
Rhino / Grasshopper<br>
 +
Grasshopper plugins:<br>
 +
- Kangaroo (physical + interactive simulations)<br>
 +
http://www.food4rhino.com/app/kangaroo-physics<br>
 +
- Karamba (structural optimization)<br>
 +
http://www.food4rhino.com/app/karamba<br>
 +
- Millipede (topological optimization)<br>
 +
http://www.sawapan.eu/<br>
 +
- Silkworm (3D printing/G-Code creation)<br>
 +
http://www.food4rhino.com/app/silkworm<br>
 +
- Kuka PRC (robotic control)<br>
 +
http://www.food4rhino.com/app/kukaprc-parametric-robot-control-grasshopper<br>
 +
- Ladybug Tools (environmental analysis and more)<br>
 +
http://www.food4rhino.com/app/ladybug-tools<br>
 +
- Weaverbird (topological mesh editing)<br>
 +
http://www.giuliopiacentino.com/weaverbird/<br>
 +
- mesh+ (mesh editing)<br>
 +
http://www.food4rhino.com/app/mesh<br><br>
 +
 
 +
<b>3D Scanning</b><br>
 +
3DF Zephyr Free (3D scanning with videos)<br>
 +
https://www.3dflow.net/3df-zephyr-pro-3d-models-from-photos/<br>
 +
Qlone (3D scanning)<br>
 +
https://www.qlone.pro/<br><br>
 +
 
 +
<b>3D Printing</b><br>
 +
Cura (3D printing software)<br>
 +
https://ultimaker.com/en/products/cura-software<br><br>
 +
 
 +
</div>
 +
 
 +
=='''COORDINATORS & TUTORS'''==
 +
 
 +
Henriette Bier, Sina Mostafavi, and Benjamin Kemper with Yu-Chou Chiang
  
 
=='''STUDENTS'''==   
 
=='''STUDENTS'''==   

Latest revision as of 12:50, 3 February 2021


MUlTI-MATERIAL ASSEMBLY (MA)

Keywords
Multi-materiality, Assembly, Material Computation, Production Computation, MultiMode Robotic Production, Hybrid Properties, Material Gradients

CONTEXT

Advancement in design computation and robotic production is leading to novel methods of material fusion on multiple scales. In architectural design, systematic methods of computing, modeling, simulating and representing multi-materiality and assembly are required. Furthermore, hacking and modifying production methods are leading to efficient and meaningful materialization processes. In this context, the workshop on Multi-material Assembly (MA) aims to explore and establish computational design to programmable production and assembly processes.

OBJECTIVE & FOCUS

The focus of this workshop is at the intersection of multi-materiality and assembly of multi-material components. The objective is to exploit informed multi-material D2RP&O approaches. Informed in this context mainly refers to structural, functional and environmental parametres. Therefore in each project one or multiple parameters will be chosen to inform the design. Modeling and production of multi-materiality as well as assembly requires integration of physical computing with materialization sequences. For instance, customized toolpath or G-code generation methods, voxel based representation of materiality, Finite Element Methods (FEM) of structural simulation, etc. Furthermore, informed assembly allows for growing larger than the size of allowed by the production setup. This entails a comprehensive understanding of structural modeling ranging from fundamental structural design concepts like degrees of freedom in multiple direction to multi-materiality itself that may improve the local or global stability and coherence of the assembly.

WORKSHOP STRUCTURE

During the MA workshop, students will work in groups and will explore 3 main aspects of assembly:

Group 1: Porous-solid interlocking systems
Group 2: Soft-rigid intertwining systems
Group 3: Physical-digital interweaving with existing topologies

DESIGN, WORK PACKAGES & DELIVERABLES

The initial input topology to this workshop will be a section part of previously designed stage-pavilion titled Echosphere (http://gsm.hyperbody.nl/index.php/Msc2G3:Group) and/or MSc 2 prototypes from previous MSc 2. This initial input is only a departure point, which during the workshop may differentiate depending on the focus of each group.
The key working packages of this workshop are divided into two main categories. First category refers to computational design methods of multi-materiality and assembly. The second emphasises the bridging of digital design approaches with physical programmable systems like 3D printers and robotic arms. Respective feedback loops shall be used as inputs that inform the design in terms of materialization.
The workshop deliverables include design computation methodologies. These computational models includes systemic representation of workflows and data exchange between multiple plugins and sub-algorithms as well as interoperability between digital and physical modules. Each group may deliver specific customized methods of material properties and behaviour simulations implemented in the design process. Moreover a flowchart diagram of process as well as a short video of design to production experiments and prototyping are considered as key deliverables of this workshop. Physical prototyping of the the design is not obligatory in the prototyping planning session. Each group in dialog with tutors will decide upon either physical prototyping or proof of concept documentation of the process. Production methods available in this workshop will be 3D printing with an ultimaker 2 and a KUKA robotic arm.

SCHEDULE

Monday 25/9
- Introduction _ Set the groups
- Design brainstorming sessions
- Hackathons and hands of computation

Tuesday 26/9
- Design sessions
- Hackathons
- Prototyping planning

Wednesday 27/9
- Design sessions
- Hackatons
- Prototyping and documentation

Thursday 28/9
- Design development
- Prototyping and or proof of concept

Friday 29/9
- Presentation
- Finetuning

Monday 2/10
- Prototypes and/or documentation of D2RP processes
- Final presentation and report

SOFTWARE & METHODS

Computation
Rhino / Grasshopper
Grasshopper plugins:
- Kangaroo (physical + interactive simulations)
http://www.food4rhino.com/app/kangaroo-physics
- Karamba (structural optimization)
http://www.food4rhino.com/app/karamba
- Millipede (topological optimization)
http://www.sawapan.eu/
- Silkworm (3D printing/G-Code creation)
http://www.food4rhino.com/app/silkworm
- Kuka PRC (robotic control)
http://www.food4rhino.com/app/kukaprc-parametric-robot-control-grasshopper
- Ladybug Tools (environmental analysis and more)
http://www.food4rhino.com/app/ladybug-tools
- Weaverbird (topological mesh editing)
http://www.giuliopiacentino.com/weaverbird/
- mesh+ (mesh editing)
http://www.food4rhino.com/app/mesh

3D Scanning
3DF Zephyr Free (3D scanning with videos)
https://www.3dflow.net/3df-zephyr-pro-3d-models-from-photos/
Qlone (3D scanning)
https://www.qlone.pro/

3D Printing
Cura (3D printing software)
https://ultimaker.com/en/products/cura-software

COORDINATORS & TUTORS

Henriette Bier, Sina Mostafavi, and Benjamin Kemper with Yu-Chou Chiang

STUDENTS

Chong Du, Erik Zanetti, Floris van Buren, Jihong Duan, Lars van Vianen, Roel Westrik, Rosanne le Roij, Tim Mechielsen, Turkuaz Nacafi

REFERENCES