Cumincad : CUMINCAD Papers : Search Results

CumInCAD is a Cumulative Index about publications in Computer Aided Architectural Design
supported by the sibling associations ACADIA, CAADRIA, eCAADe, SIGraDi, ASCAAD and CAAD futures

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_id	acadia16_224
id	acadia16_224
authors	Schwinn, Tobias; Krieg, Oliver David; Menges, Achim
year	2016
title	Robotic Sewing: A Textile Approach Towards the Computational Design and Fabrication of Lightweight Timber Shells
doi	https://doi.org/10.52842/conf.acadia.2016.224
source	ACADIA // 2016: POSTHUMAN FRONTIERS: Data, Designers, and Cognitive Machines [Proceedings of the 36th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-77095-5] Ann Arbor 27-29 October, 2016, pp. 224-233
summary	Unlike any other building material, timber has seen numerous innovations in design, manufacturing, and assembly processes in recent years. Currently available technology not only allows architects to freely shape building elements but also to define their micro- or macroscopic material make-up and therefore the material itself. At the same time, timber shells have become a focus of research in wood architecture by rethinking both construction typologies and material application. Their main advantage, however, also poses a challenge to its construction: As the shell is both the load-bearing structure as well as enclosure, its segmentation and the individual segment’s connections become increasingly important. Their complex and often differentiated geometries do not allow for standardized timber joints, and with decreasing material thickness, conventional connection techniques become less feasible. The research presented in this paper investigates textile strategies for the fabrication of ultra-lightweight timber shells in architecture. Specifically, a robotic sewing method is developed in conjunction with a computational design method for the development of a new construction system that was evaluated through a large-scale prototype building.
keywords	textile connection, robotic fabrication, timber construction, embedded responsiveness
series	ACADIA
type	paper
email
last changed	2022/06/07 07:56

_id	ecaade2016_113
id	ecaade2016_113
authors	Poinet, Paul, Baharlou, Ehsan, Schwinn, Tobias and Menges, Achim
year	2016
title	Adaptive Pneumatic Shell Structures - Feedback-driven robotic stiffening of inflated extensible membranes and further rigidification for architectural applications
doi	https://doi.org/10.52842/conf.ecaade.2016.1.549
source	Herneoja, Aulikki; Toni Österlund and Piia Markkanen (eds.), Complexity & Simplicity - Proceedings of the 34th eCAADe Conference - Volume 1, University of Oulu, Oulu, Finland, 22-26 August 2016, pp. 549-558
summary	The paper presents the development of a design framework that aims to reduce the complexity of designing and fabricating free-form inflatables structures, which often results in the generation of very complex geometries. In previous research the form-finding potential of actuated and constrained inflatable membranes has already been investigated however without a focus on fabrication (Otto 1979). Consequently, in established design-to-fabrication approaches, complex geometry is typically post-rationalized into smaller parts and are finally fabricated through methods, which need to take into account cutting pattern strategies and material constraints. The design framework developed and presented in this paper aims to transform a complex design process (that always requires further post-rationalization) into a more integrated one that simultaneously unfolds in a physical and digital environment - hence the term cyber-physical (Menges 2015). At a full scale, a flexible material (extensible membrane, e.g. latex) is actuated through inflation and modulated through additive stiffening processes, before being completely rigidified with glass fibers and working as a thin-shell under compression.
wos	WOS:000402063700060
keywords	pneumatic systems; robotic fabrication; feedback strategy; cyber-physical; scanning processes
series	eCAADe
email
last changed	2022/06/07 08:00

_id	ijac201614104
id	ijac201614104
authors	Wood, Dylan Marx; David Correa, Oliver David Krieg and Achim Menges
year	2016
title	Material computation—4D timber construction: Towards building-scale hygroscopic actuated, self-constructing timber surfaces
source	International Journal of Architectural Computing vol. 14 - no. 1, 49-62
summary	The implementation of active and responsive materials in architecture and construction allows for the replacement of digitally controlled mechanisms with material-based systems that can be designed and programmed with the capacity to compute and execute a behavioral response. The programming of such systems with increasingly specific response requires a material-driven computational design and fabrication strategy. This research presents techniques and technologies for significantly upscaling hygroscopically actuated timber-based systems for use as self-constructing building surfaces. The timber’s integrated hygroscopic characteristics combined with computational design techniques and existing digital fabrication methods allow for a designed processing and reassembly of discrete wood elements into large-scale multi element bilayer surfaces. This material assembly methodology enables the design and control of the encoded direction and magnitude of humidity-actuated responsive curvature at an expanded scale. Design, simulation, and material assembly tests are presented together with formal and functional configurations that incorporate self-constructing and self-rigidizing surface strategies. The presented research and prototypes initiate a shift toward a large-scale, self-construction methodology.
keywords	Hygroscopic, self-forming, computational design, autonomous actuation, wood structures
series	journal
last changed	2016/06/13 08:34

_id	ecaade2016_055
id	ecaade2016_055
authors	Baranovskaya, Yuliya, Prado, Marshall, Dörstelmann, Moritz and Menges, Achim
year	2016
title	Knitflatable Architecture - Pneumatically Activated Preprogrammed Knitted Textiles
doi	https://doi.org/10.52842/conf.ecaade.2016.1.571
source	Herneoja, Aulikki; Toni Österlund and Piia Markkanen (eds.), Complexity & Simplicity - Proceedings of the 34th eCAADe Conference - Volume 1, University of Oulu, Oulu, Finland, 22-26 August 2016, pp. 571-580
summary	Textiles are widely used in architecture for tensile structures, as they are lightweight and can easily span large distances. These structures typically require an external framework for a support. Inflatable structures are self-supporting but are limited to relatively simple forms or require complex and predetermined cut patterns. The development of an adaptive and programmable textile system with an integrative method for pneumatic activation would create a novel self-supporting structure with high degree of design and architectural potential. This creates a highly integrative hybrid system where the generic pneumatic membranes are constrained by the differentiated knitted textile skin that is stretched in several directions under air pressure. This allows for an innovative, lightweight, easily transportable design, where the preprogrammed knitting pattern defines the structure, geometry and formation, activated under pneumatic pressure.
wos	WOS:000402063700062
keywords	programming textiles; binary textiles; analogue computing; air inflation; grading textile properties
series	eCAADe
email
last changed	2022/06/07 07:54

_id	acadia16_184
id	acadia16_184
authors	Vasey; Lauren; Long Nguyen; Tovi Grossman; Heather Kerrick; Danil Nagy; Evan Atherton; David Thomasson; Nick Cote; David Benjamin; George Fitzmaurice; Achim Menges
year	2016
title	Collaborative Construction: Human and Robotic Collaboration Enabling the Fabrication and Assembly of a Filament-Wound Structure
doi	https://doi.org/10.52842/conf.acadia.2016.184
source	ACADIA // 2016: POSTHUMAN FRONTIERS: Data, Designers, and Cognitive Machines [Proceedings of the 36th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-77095-5] Ann Arbor 27-29 October, 2016, pp. 184-195
summary	In this paper, we describe an interdisciplinary project and live-exhibit that investigated whether untrained humans and robots could work together collaboratively towards the common goal of building a large-scale structure composed out of robotically fabricated modules using a filament winding process. We describe the fabrication system and exhibition setup, including a custom end effector and tension control mechanism, as well as a collaborative fabrication process in which instructions delivered via wearable devices enable the trade-off of production and assembly tasks between human and robot. We describe the necessary robotic developments that facilitated a live fabrication process, including a generic robot inverse kinematic solver engine for non-spherical wrist robots, and wireless network communication connecting hardware and software. In addition, we discuss computational strategies for the fiber syntax generation and robotic motion planning which mitigated constraints such as reachability, axis limitations, and collisions, and ensured predictable and therefore safe motion in a live exhibition setting. We discuss the larger implications of this project as a case study for handling deviations due to non-standardized materials or human error, as well as a means to reconsider the fundamental separation of human and robotic tasks in a production workflow. Most significantly, the project exemplifies a hybrid domain of human and robot collaboration in which coordination and communication between robots, people, and devices can enhance the integration of robotic processes and computational control into the characteristic processes of construction.
keywords	machin vision, cyber-physical systems, internet of things, robotic fabrication, human robot collaboration, sensate systems
series	ACADIA
type	paper
email
last changed	2022/06/07 07:58

_id	acadia16_154
id	acadia16_154
authors	Brugnaro, Giulio; Baharlou, Ehsan; Vasey, Lauren; Menges, Achim
year	2016
title	Robotic Softness: An Adaptive Robotic Fabrication Process for Woven Structures
doi	https://doi.org/10.52842/conf.acadia.2016.154
source	ACADIA // 2016: POSTHUMAN FRONTIERS: Data, Designers, and Cognitive Machines [Proceedings of the 36th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-77095-5] Ann Arbor 27-29 October, 2016, pp. 154-163
summary	This paper investigates the potential of behavioral construction strategies for architectural production through the design and robotic fabrication of three-dimensional woven structures inspired by the behavioral fabrication logic used by the weaverbird during the construction of its nest. Initial research development led to the design of an adaptive robotic fabrication framework composed of an online agent-based system, a custom weaving end-effector and a coordinated sensing strategy utilizing 3D scanning.The outcome of the behavioral weaving process could not be predetermined a priori in a digital model, but rather emerged out of the negotiation among design intentions, fabrication constraints, performance criteria, material behaviors and specific site conditions. The key components of the system and their role in the fabrication process are presented both theoretically and technically, while the project serves as a case study of a robotic production method envisioned as a soft system: a flexible and adaptable framework in which the moment of design unfolds simultaneously with fabrication, informed by a constant flow of sensory information.
keywords	soft systems, agent-based systems, robotic fabrication, sensate systems
series	ACADIA
type	paper
email
last changed	2022/06/07 07:54

_id	acadia16_62
id	acadia16_62
authors	Rusenova, Gergana; Dierichs, Karola; Baharlou, Ehsan; Menges, Achim
year	2016
title	Feedback- and Data-driven Design for Aggregate Architectures: Analyses of Data Collections for Physical and Numerical Prototypes of Designed Granular Materials
doi	https://doi.org/10.52842/conf.acadia.2016.062
source	ACADIA // 2016: POSTHUMAN FRONTIERS: Data, Designers, and Cognitive Machines [Proceedings of the 36th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA) ISBN 978-0-692-77095-5] Ann Arbor 27-29 October, 2016, pp.62-72
summary	This project contributes to the investigations in the field of aggregate architectures by linking two research areas: the numerical simulation of aggregate formations, and a concept for an online-controlled pneumatic formwork system. This paper introduces a novel approach for constructing with designed particles based on a feedback process. The overall aim was to investigate the capacity of aggregates as an architectural material system, which create emergent spatial formations. Initially the particles´ micro-mechanical behavior and the fragile stability of the formations were analyzed using numerical simulations. Based on this, an online-controlled inflatable formwork system was developed. The formwork was designed to react to the actual stability state of an aggregate formation; for this, a statistical set of simulation data was gathered, which directly informed the physical system. This overall concept was proven and verified in a one-to-one scaled physical model. The methods developed within this research provide a first set of baselines for comparison between the behavior of simulated and physical designed granular materials.
keywords	simulations, designed particles, feedback-driven design, embedded responsiveness
series	ACADIA
type	paper
email
last changed	2022/06/07 07:56

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