Towards digital automation flexibility in large-scale timber construction: integrative robotic prefabrication and co-design of the BUGA Wood Pavilion

Wagner, Hans Jakob; Álvarez, Martín; Groenewolt, Abel; Menges, Achim

doi:10.1007/s41693-020-00038-5

Cited by 62 publications

(25 citation statements)

References 31 publications

(27 reference statements)

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“…In addition, digital tools and innovations, such as robotic fabrication, are increasingly gaining application in modern timber construction. Through innovative manufacturing methods, natural-based materials can be made more industrially suitable to further advance the research and development of both sustainable materials and constructions [29,30].…”

Section: Discussionmentioning

confidence: 99%

The Dilemma of Balancing Design for Impact Sound with Environmental Performance in Wood Ceiling Systems—A Building Physics Perspective

et al. 2021

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Due to the high consumption of resources and energy in the construction sector, the development of resource-efficient and sustainable construction solutions is gaining increasing attention. The awareness of sustainability and resource conservation results in the interest of using natural and renewable materials in contemporary architecture. Timber construction methods offer both constructive and ecological potential for sustainable solutions. From a building physics perspective, the acoustic performance of lightweight buildings, such as those made of timber, presents a challenge. Even if standard requirements are met, the increased low-frequency sound transmission typical for light-weight construction can cause discomfort and is already the subject of questions in building physics, which are currently increasingly extending to timber construction. Within the framework of a holistic approach, this paper compares the problem of acoustic properties, design optimizations and the ecological properties of timber-frame and solid timber construction components. The comparison with heavy materials, such as concrete, shows the relation of acoustic optimization with the change of the environmental profile. In order to establish the interaction between acoustic quality of wooden ceiling constructions and their ecological characteristics, this article aims to demonstrate the potential of materials used in the building sector under ecological aspects considering a life cycle analysis.

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Section: Discussionmentioning

confidence: 99%

The Dilemma of Balancing Design for Impact Sound with Environmental Performance in Wood Ceiling Systems—A Building Physics Perspective

et al. 2021

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“…The co‐design method created for this project generated the shape of each component for the pavilion according to the architectural design intent and the structural loading 9,10 . The conception and development of the transportable robotic manufacturing unit to be used was also an integral part of the co‐design 11 . Only this highly integrative process made it possible to manufacture 376 different panel segments with 17 000 different finger joints in accordance with the diverse design requirements for the overall structure and its details with an accuracy of three tenths of a millimeter.…”

Section: Two Case Studies Showcasing the Innovation Potential Of Co‐designmentioning

confidence: 99%

Integrative computational design and construction: Rethinking architecture digitally

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Menges

et al. 2021

Civil Engineering Design

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Increasing the construction capacity, while at the same time significantly reducing harmful emissions and consumption of nonrenewable resources, and still providing a liveable and affordable built environment, provides a great challenge for future construction. In order to achieve this, both the productivity of construction processes and the energy and resource efficiency of construction systems have to be improved in a reciprocal process. Digital technologies make it possible to address these challenges in novel ways. The vision of this Cluster of Excellence IntCDC at the University of Stuttgart and the Max Planck Institute for Intelligent Systems is to harness the full potential of digital technologies to rethink design and construction based on integration and interdisciplinarity, with the goal of laying the methodological foundations to profoundly modernize the design and construction process and related building systems by adopting a systematic, holistic and integrative computational approach. One key objective is to develop an overarching methodology of “co‐designing” methods, processes and systems based on interdisciplinary research encompassing architecture, structural engineering, building physics, engineering geodesy, manufacturing and systems engineering, computer science and robotics, and humanities and social sciences. In this way, the Cluster aims to address the ecological, economic and social challenges and to provide the prerequisites for a high‐quality and sustainable built environment and a digital building culture.

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“…Die für dieses Projekt geschaffene Co‐Design‐Methode generierte die Form jedes einzelnen Bauteils für den Pavillon gemäß der architektonischen Entwurfsabsicht und der statischen Beanspruchung [9, 10]. Auch die Konzeption und Entwicklung der zum Einsatz kommenden transportablen robotischen Fertigungseinheit war integraler Bestandteil des Co‐Designs [11]. Erst dieser hochintegrative Prozess ermöglichte die Fertigung von 376 unterschiedlichen Plattensegmenten mit 17 000 verschiedenen Keilzinkenverbindungen gemäß den vielfaltigen konstruktiven Anforderungen an die Gesamtstruktur und deren Details mit einer Genauigkeit von drei Zehntelmillimetern.…”

Section: Zwei Fallbeispiele Für Die Innovationsstärke Von Co‐designunclassified

Integratives computerbasiertes Planen und Bauen: Architektur digital neu denken

et al. 2021

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Die Herausforderung an das Bauen der Zukunft besteht darin, mehr zu bauen, dabei weniger Schadstoffe zu emittieren und weniger endliche Ressourcen zu verbrauchen und trotzdem eine qualitätsvolle und lebenswerte gebaute Umwelt zu schaffen. In einem sich wechselseitig beeinflussenden Prozess müssen hierfür sowohl die Produktivität der Bauprozesse als auch die Energie‐ und Ressourceneffizienz der Bausysteme verbessert werden. Digitale Technologien bieten neue Lösungsansätze für diese Herausforderungen. Ziel des Exzellenzclusters IntCDC an der Universität Stuttgart und dem Max‐Planck‐Institut für Intelligente Systeme ist es, das volle Potenzial digitaler Technologien zu nutzen, um das Planen und Bauen in einem integrativen und interdisziplinären Ansatz neu zu denken und damit die methodischen Grundlagen für eine umfassende Modernisierung des Bauschaffens zu legen. Eine zentrale Zielsetzung ist die Entwicklung einer übergeordneten Methodologie des „Co‐Design“ von Methoden, Prozessen und Systemen, basierend auf interdisziplinärer Forschung zwischen den Bereichen Architektur, Bauingenieurwesen, Ingenieurgeodäsie, Produktions‐ und Systemtechnik, Informatik und Robotik sowie Geistes‐ und Sozialwissenschaften. So sollen Lösungswege für die ökologischen, ökonomischen und sozialen Herausforderungen aufgezeigt und die Voraussetzungen für eine qualitätsvolle, lebenswerte und nachhaltige gebaute Umwelt sowie für eine digitale Baukultur geschaffen werden.

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Towards digital automation flexibility in large-scale timber construction: integrative robotic prefabrication and co-design of the BUGA Wood Pavilion

Cited by 62 publications

References 31 publications

The Dilemma of Balancing Design for Impact Sound with Environmental Performance in Wood Ceiling Systems—A Building Physics Perspective

The Dilemma of Balancing Design for Impact Sound with Environmental Performance in Wood Ceiling Systems—A Building Physics Perspective

Integrative computational design and construction: Rethinking architecture digitally

Integratives computerbasiertes Planen und Bauen: Architektur digital neu denken

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