96 research outputs found
Nature inspired architecture: Integrative computational design and fabrication for filamentous structures
Inspiration found in nature, together with advances in computational design and robotic fabrication, challenge existing approaches in building technology in a surprising manner, or even point out completely different possibilities. Biology offers an almost inexhaustible reservoir of principles of form, structure and process that can be transferred to architecture. At the same time, computation profoundly transforms the building industry. Our presentation will introduce ways of tapping the full potential of digital technologies in architecture and construction through inspiration by nature, in order to go beyond the mere digitalization of established planning procedures and the automation of existing building processes towards truly integrative computational design and construction. Along the example of large-scale, load-bearing, fiber-composite structures, we will show how a biomimetic approach enables creating architecture that is both highly effective and efficient, as well as explorative and expressive.
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Designing architectural materials: from granular form to functional granular material
Designed granular materials are a novel class of architectural material system. Following one of the key paradigms of designed matter, material form and material function are closely interrelated in these systems. In this context, the article aims to contribute a parametric particle design model as an interface for this interrelation. A granular material is understood as an aggregation of large numbers of individual particles between which only short-range repulsive contact forces are acting. Granular materials are highly pertinent material systems for architecture. Due to the fact that they can act both as a solid and a liquid, they can be recycled and reconfigured multiple times and are thus highly sustainable. Designed granular materials have the added potential that the function of the granular material can be calibrated through the definition of the particlesâ form. Research on the design of granular materials in architecture is nascent. In physics they have been explored mainly with respect to different particle shapes. However, no coherent parametric particle design model of designed particle shapes for granular material systems in architecture has yet been established which considers both fabrication constraints and simulation requirements. The parametric particle design model proposed in this article has been based on a design system which has been developed through feasibility tests and simulations conducted in research and teaching. Based on this design system the parametric particle design model is developed integrating both fabrication constraints for architecture-scale particle systems and the geometric requirements of established simulation methods for granular materials. Initially the design system and related feasibility tests are presented. The parametric particle design model resulting from that is then described in detail. Directions of further research are discussed especially with respect to the integration of the parametric particle design model in âinverseâ design methods.Deutsche Forschungsgemeinschafthttps://doi.org/10.13039/501100001659Peer Reviewe
Robust Task and Motion Planning for Long-Horizon Architectural Construction Planning
Integrating robotic systems in architectural and construction processes is of
core interest to increase the efficiency of the building industry. Automated
planning for such systems enables design analysis tools and facilitates faster
design iteration cycles for designers and engineers. However, generic
task-and-motion planning (TAMP) for long-horizon construction processes is
beyond the capabilities of current approaches. In this paper, we develop a
multi-agent TAMP framework for long horizon problems such as constructing a
full-scale building. To this end we extend the Logic-Geometric Programming
framework by sampling-based motion planning,a limited horizon approach, and a
task-specific structural stability optimization that allow an effective
decomposition of the task. We show that our framework is capable of
constructing a large pavilion built from several hundred geometrically unique
building elements from start to end autonomously
Monitoring the production process of lightweight fibrous structures using terrestrial laser scanning
The Cluster of Excellence Integrative Computational Design and Construction for Architecture at the University of Stuttgart brings together various disciplines to jointly develop amongst other things a better of processes in the manufacturing and construction domain. One of the clusterâs aims is to create new solutions for the construction of lightweight fibrous structures using coreless winding of lightweight fiber composite systems. For this purpose, a precise geometry and an understanding of the fibersâ behavior during the production process are of major importance. The fibersâ production process is monitored by repeatedly scanning the fibers during different stages of the process using a terrestrial laser scanner. In order to determine the geometry of the fibersâ axes as well as their cross-sections, two different strategies are used. The first strategy focuses on the segmentation of several straight lines between two intersection points. For the comparison of the individual fabrication steps, the positions of the intersection points are contrasted. For the cross-sectional areas of the fibers, orthogonal planes of intersection are then defined and all points within a predefined area are projected onto this plane. Then the area is calculated using a convex hull. In the second strategy, the fibersâ main axes are represented by best-fitting B-spline curves. The borders of the cross-sections of interest are also approximated by best-fitting B-spline curves, forming the basis for the final determination of the cross-sectional areas. In this case study two epochs are analyzed with a deformation of the size of around 1cm. For both epochs the cross-sections are calculated in cm steps
Asymptotic Geodesic Hybrid Timber Gridshell
This paper presents a strategy to design and build strained timber gridshells
from exclusively straight timber planks, which are interwoven and elastically deployed
into a doubly curved web. For this purpose, we combine asymptotic (A) and geodesic
(G) curves into hybrid AAG-webs on curved surfaces.We present a digital method to
design and geometrically optimize the timber AAG-webs to include equal intersection
angles and geodesic boundaries. This new construction system benefits from the targeted
use of the two differing bending axes of timber planks for flexibility and rigidity.
The flat geodesic planks are interlaced at the midpoint of the asymptotic beams to
create a tri-hex pattern, which lowers the buckling length and decisively increases the
overall stiffness. As a proof of concept, a large-scale timber gridshell covering an area
of 60m2 was designed and built.We document the construction process of manufacturing,
prefabrication, elastic deformation, on-site assembly, and installation of the
polycarbonate cover to verify constructive tolerances and feasibility. The structure is
tested and simulated to validate our computational results
Cross-Sectional 4D-Printing: Upscaling Self-Shaping Structures with Differentiated Material Properties Inspired by the Large-Flowered Butterwort (Pinguicula grandiflora)
Extrusion-based 4D-printing, which is an emerging field within additive manufacturing, has enabled the technical transfer of bioinspired self-shaping mechanisms by emulating the functional morphology of motile plant structures (e.g., leaves, petals, capsules). However, restricted by the layer-by-layer extrusion process, much of the resulting works are simplified abstractions of the pinecone scaleâs bilayer structure. This paper presents a new method of 4D-printing by rotating the printed axis of the bilayers, which enables the design and fabrication of self-shaping monomaterial systems in cross sections. This research introduces a computational workflow for programming, simulating, and 4D-printing differentiated cross sections with multilayered mechanical properties. Taking inspiration from the large-flowered butterwort (Pinguicula grandiflora), which shows the formation of depressions on its trap leaves upon contact with prey, we investigate the depression formation of bioinspired 4D-printed test structures by varying each depth layer. Cross-sectional 4D-printing expands the design space of bioinspired bilayer mechanisms beyond the XY plane, allows more control in tuning their self-shaping properties, and paves the way toward large-scale 4D-printed structures with high-resolution programmability
digital design and wooden architecture for arte sella land art park
Digital design is increasingly sinking the construction sector, shaping and validating architecture according to various criteria and introducing the wood industry to the 4.0 approach. Within the study entitled "Architecture at Arte Sella", parametric design, structural validations and CNC procedures are exploited to help define, control and assess several architectural woodworks, created with famous designers. This contribution describes the design and construction experiences of Atsushi Kitagawara (2017) and Kengo Kuma (2018â2019), the two masterpieces installed in the land art park of Arte Sella (Trento, Italy) and developed, thanks to the Politecnico di Milano team, from design to mock-ups, testing and construction
Modularisation Strategies for Individualised Precast ConstructionâConceptual Fundamentals and Research Directions
Modular precast construction is a methodological approach to reduce environmental impacts and increase productivity when building with concrete. Constructions are segmented into similar precast concrete elements, prefabricated with integrated quality control, and assembled just-in-sequence on site. Due to the automatised prefabrication, inaccuracies are minimised and the use of high-performance materials is enabled. As a result, the construction process is accelerated, and the modules can be designed to be lightweight and resource-efficient. This contribution presents the fundamentals of modular constructions made from precast concrete components. Then, to elaborate the requirements of a contemporary modular precast construction, the historic developments are described. Further, concepts and technical processesâcomprehensible to non-expert readersâare introduced to formalise the discussion about the current state-of-the-art methods. Three case studies treating ongoing research are introduced and related to the conceptual fundamentals. The research is evaluated with regard to current barriers and future directions. In conclusion, modular precast construction is able to reduce emissions and increase productivity in the sector if researchers and firms coordinate the development of suitable technologies that bring value to critical stakeholders
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