research-article

Computational design of cold bent glass façades

Authors:

Konstantinos Gavriil,

Ruslan Guseinov,

Paul Henderson,

Helmut Pottmann,

Bernd BickelAuthors Info & Claims

ACM Transactions on Graphics (TOG), Volume 39, Issue 6

Article No.: 208, Pages 1 - 16

https://doi.org/10.1145/3414685.3417843

Published: 27 November 2020 Publication History

Abstract

Cold bent glass is a promising and cost-efficient method for realizing doubly curved glass façades. They are produced by attaching planar glass sheets to curved frames and must keep the occurring stress within safe limits. However, it is very challenging to navigate the design space of cold bent glass panels because of the fragility of the material, which impedes the form finding for practically feasible and aesthetically pleasing cold bent glass façades. We propose an interactive, data-driven approach for designing cold bent glass façades that can be seamlessly integrated into a typical architectural design pipeline. Our method allows non-expert users to interactively edit a parametric surface while providing real-time feedback on the deformed shape and maximum stress of cold bent glass panels. The designs are automatically refined to minimize several fairness criteria, while maximal stresses are kept within glass limits. We achieve interactive frame rates by using a differentiable Mixture Density Network trained from more than a million simulations. Given a curved boundary, our regression model is capable of handling multistable configurations and accurately predicting the equilibrium shape of the panel and its corresponding maximal stress. We show that the predictions are highly accurate and validate our results with a physical realization of a cold bent glass surface.

Supplementary Material

MP4 File (a208-gavriil.mp4)

Download
215.89 MB

MP4 File (3414685.3417843.mp4)

Presentation video

Download
463.38 MB

References

[1]

Sigrid Adriaenssens, Philippe Block, Diederik Veenendaal, and Chris Williams. 2014. Shell Structures for Architecture: Form Finding and Optimization. Routledge.

[2]

Jimmy Lei Ba, Jamie Ryan Kiros, and Geoffrey E. Hinton. 2016. Layer Normalization. arXiv:1607.06450

[3]

Jernej Barbič and Doug L. James. 2005. Real-Time Subspace Integration for St. Venant-Kirchhoff Deformable Models. ACM Trans. Graph. 24, 3 (July 2005), 982--990.

Digital Library

[4]

Benjamin Beer. 2015. Structural Silicone Sealed Cold-Bent Glass-High-Rise Projects Experience Leading to a New Design Concept. GPD Glass Performance Days (2015), 235--240.

[5]

Jan Belis, Bart Inghelbrecht, Rudy Van Impe, and Dieter Callewaert. 2007. Cold bending of laminated glass panels. Heron 52, 1--2 (2007), 123--146.

[6]

Aysu Berk and Harry Giles. 2017. Quadrilateral panelization of freeform surface structures. Automation in Construction 76 (2017), 36 -- 44.

[7]

Amit H. Bermano, Thomas Funkhouser, and Szymon Rusinkiewicz. 2017. State of the Art in Methods and Representations for Fabrication-Aware Design. Computer Graphics Forum 36, 2 (2017), 509--535.

Digital Library

[8]

Bernd Bickel, Paolo Cignoni, Luigi Malomo, and Nico Pietroni. 2018. State of the Art on Stylized Fabrication. Computer Graphics Forum 37, 6 (2018), 325--342.

[9]

Christopher M. Bishop. 2006. Pattern Recognition and Machine Learning. Springer-Verlag New York.

Digital Library

[10]

Desai Chen, David I. W. Levin, Shinjiro Sueda, and Wojciech Matusik. 2015. Data-Driven Finite Elements for Geometry and Material Design. ACM Trans. Graph. 34, 4, Article 74 (July 2015), 10 pages.

Digital Library

[11]

Jiong Chen, Hujun Bao, Tianyu Wang, Mathieu Desbrun, and Jin Huang. 2018. Numerical Coarsening Using Discontinuous Shape Functions. ACM Trans. Graph. 37, 4, Article 120 (July 2018), 12 pages.

Digital Library

[12]

Peter W. Christensen and Anders Klarbring. 2008. An Introduction to Structural Optimization. Springer Netherlands.

[13]

Djork-Arné Clevert, Thomas Unterthiner, and Sepp Hochreiter. 2015. Fast and Accurate Deep Network Learning by Exponential Linear Units (ELUs). arXiv:1511.07289

[14]

Kyriaki Corinna Datsiou. 2017. Design and performance of cold bent glass. Ph.D. Dissertation. University of Cambridge.

[15]

Michael Eigensatz, Martin Kilian, Alexander Schiftner, Niloy J. Mitra, Helmut Pottmann, and Mark Pauly. 2010. Paneling Architectural Freeform Surfaces. ACM Trans. Graph. 29, 4, Article 45 (July 2010), 10 pages.

Digital Library

[16]

Philipp Eversmann, André Ihde, and Christian Louter. 2016a. Low Cost Double Curvature---Exploratory Computational Modelling, FE-analysis and Prototyping of Cold-Bent Glass. In Challenging Glass Conference Proceedings, Vol. 5. 81--92.

[17]

Philipp Eversmann, Eike Schling, André Ihde, and Christian Louter. 2016b. Low-Cost Double Curvature: Geometrical and Structural Potentials of Rectangular, Cold-Bent Glass Construction. In Proceedings of IASS Annual Symposia. IASS. https://www.ingentaconnect.com/content/iass/piass/2016/00002016/00000016/art00016

[18]

Thiemo Fildhuth and Jan Knippers. 2011. Geometrie und Tragverhalten von doppelt gekrümmten Ganzglasschalen aus kalt verformten Glaslaminaten. Stahlbau 80, S1 (2011), 31--44.

[19]

Lawson Fulton, Vismay Modi, David Duvenaud, David I. W. Levin, and Alec Jacobson. 2019. Latent-space Dynamics for Reduced Deformable Simulation. Computer Graphics Forum 38, 2 (2019), 379--391.

[20]

Francisca Gil-Ureta, Nico Pietroni, and Denis Zorin. 2019. Structurally optimized shells. arXiv:1904.12240

[21]

Yotam Gingold, Adrian Secord, Jefferson Han, Eitan Grinspun, and Denis Zorin. 2004. A Discrete Model for Inelastic Deformation of Thin Shells. (01 2004).

[22]

James Glymph, Dennis Shelden, Cristiano Ceccato, Judith Mussel, and Hans Schober. 2004. A parametric strategy for free-form glass structures using quadrilateral planar facets. Automation in Construction 13, 2 (2004), 187 -- 202.

[23]

Eitan Grinspun, Yotam Gingold, Jason Reisman, and Denis Zorin. 2006. Computing discrete shape operators on general meshes. Computer Graphics Forum 25, 3 (2006), 547--556.

[24]

Ruslan Guseinov, Eder Miguel, and Bernd Bickel. 2017. CurveUps: Shaping Objects from Flat Plates with Tension-Actuated Curvature. ACM Trans. Graph. 36, 4, Article 64 (July 2017), 12 pages.

Digital Library

[25]

Kaiming He, Xiangyu Zhang, Shaoqing Ren, and Jian Sun. 2016. Deep Residual Learning for Image Recognition. In 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR). 770--778.

[26]

Diederik P. Kingma and Jimmy Lei Ba. 2014. Adam: A Method for Stochastic Optimization. (2014). arXiv:1607.06450

[27]

Warner T. Koiter. 1966. On the nonlinear theory of thin elastic shells. Proc. Koninkl. Ned. Akad. van Wetenschappen, Series B 69 (1966), 1--54.

[28]

Mina Konaković-Luković, Julian Panetta, Keenan Crane, and Mark Pauly. 2018. Rapid Deployment of Curved Surfaces via Programmable Auxetics. ACM Trans. Graph. 37, 4, Article 106 (July 2018), 13 pages.

Digital Library

[29]

Yang Liu, Helmut Pottmann, Johannes Wallner, Yong-Liang Yang, and Wenping Wang. 2006. Geometric Modeling with Conical Meshes and Developable Surfaces. ACM Trans. Graph. 25, 3 (July 2006), 681--689.

Digital Library

[30]

Yang Liu, Weiwei Xu, Jun Wang, Lifeng Zhu, Baining Guo, Falai Chen, and Guoping Wang. 2011. General Planar Quadrilateral Mesh Design Using Conjugate Direction Field. ACM Trans. Graph. 30, 6 (Dec. 2011), 1--10.

Digital Library

[31]

Ran Luo, Tianjia Shao, Huamin Wang, Weiwei Xu, Xiang Chen, Kun Zhou, and Yin Yang. 2018. NNWarp: Neural Network-based Nonlinear Deformation. IEEE TVCG (2018).

[32]

Luigi Malomo, Jesús Pérez, Emmanuel Iarussi, Nico Pietroni, Eder Miguel, Paolo Cignoni, and Bernd Bickel. 2018. FlexMaps: Computational Design of Flat Flexible Shells for Shaping 3D Objects. ACM Trans. Graph. 37, 6, Article 241 (Dec. 2018), 14 pages.

Digital Library

[33]

Vittorio Megaro, Bernhard Thomaszewski, Maurizio Nitti, Otmar Hilliges, Markus Gross, and Stelian Coros. 2015. Interactive Design of 3D-Printable Robotic Creatures. ACM Trans. Graph. 34, 6, Article 216 (Oct. 2015), 9 pages.

Digital Library

[34]

Romain Mesnil, Cyril Douthe, Olivier Baverel, and Bruno Leger. 2017. Marionette Meshes: Modelling free-form architecture with planar facets. International Journal of Space Structures 32, 3--4 (2017), 184--198.

[35]

Niloy J. Mitra, Iasonas Kokkinos, Paul Guerrero, Nils Thuerey, Vladimir Kim, and Leonidas Guibas. 2019. CreativeAI: Deep Learning for Graphics. In ACM SIGGRAPH 2019 Courses (SIGGRAPH '19). Association for Computing Machinery, New York, NY, USA, Article 8, 265 pages.

Digital Library

[36]

Przemyslaw Musialski, Thomas Auzinger, Michael Birsak, Michael Wimmer, and Leif Kobbelt. 2015. Reduced-Order Shape Optimization Using Offset Surfaces. ACM Trans. Graph. 34, 4, Article 102 (July 2015), 9 pages.

Digital Library

[37]

J. Panetta, M. Konaković-Luković, F. Isvoranu, E. Bouleau, and M. Pauly. 2019. X-Shells: A New Class of Deployable Beam Structures. ACM Trans. Graph. 38, 4, Article 83 (July 2019), 15 pages.

Digital Library

[38]

Davide Pellis, Martin Kilian, Felix Dellinger, Johannes Wallner, and Helmut Pottmann. 2019. Visual Smoothness of Polyhedral Surfaces. ACM Trans. Graph. 38, 4, Article 31 (July 2019), 11 pages.

Digital Library

[39]

Lionel Du Peloux, Olivier Baverel, Jean-François Caron, and Frédéric Tayeb. 2013. From shape to shell: a design tool to materialize freeform shapes using gridshell structures. In Rethinking Prototyping: Proceedings of the Design Modelling Symposium Berlin 2013. Berlin, Germany. https://hal.archives-ouvertes.fr/hal-01199030

[40]

Alexander Pentland and John Williams. 1989. Good Vibrations: Modal Dynamics for Graphics and Animation. SIGGRAPH Comput. Graph. 23, 3 (July 1989), 207--214.

Digital Library

[41]

Tobias Pfaff, Rahul Narain, Juan Miguel de Joya, and James F. O'Brien. 2014. Adaptive Tearing and Cracking of Thin Sheets. ACM Trans. Graph. 33, 4, Article 110 (July 2014), 9 pages.

Digital Library

[42]

Helmut Pottmann, Michael Eigensatz, Amir Vaxman, and Johannes Wallner. 2015. Architectural Geometry. Comput. Graph. 47, C (April 2015), 145--164.

Digital Library

[43]

Helmut Pottmann, Alexander Schiftner, Pengbo Bo, Heinz Schmiedhofer, Wenping Wang, Niccolo Baldassini, and Johannes Wallner. 2008. Freeform Surfaces from Single Curved Panels. ACM Trans. Graph. 27, 3 (Aug. 2008), 1--10.

Digital Library

[44]

Adriana Schulz, Jie Xu, Bo Zhu, Changxi Zheng, Eitan Grinspun, and Wojciech Matusik. 2017. Interactive Design Space Exploration and Optimization for CAD Models. ACM Trans. Graph. 36, 4, Article 157 (July 2017), 14 pages.

Digital Library

[45]

Christian Schumacher, Bernhard Thomaszewski, and Markus Gross. 2016. Stenciling: Designing Structurally-Sound Surfaces with Decorative Patterns. Computer Graphics Forum 35, 5 (2016), 101--110.

Digital Library

[46]

Christian Schumacher, Jonas Zehnder, and Moritz Bächer. 2018. Set-in-Stone: Worst-Case Optimization of Structures Weak in Tension. ACM Trans. Graph. 37, 6, Article 252 (Dec. 2018), 13 pages.

Digital Library

[47]

Ondrej Stava, Juraj Vanek, Bedrich Benes, Nathan Carr, and Radomír Měch. 2012. Stress Relief: Improving Structural Strength of 3D Printable Objects. ACM Trans. Graph. 31, 4, Article 48 (July 2012), 11 pages.

Digital Library

[48]

Sivan Toledo. 2003. TAUCS, A Library of Sparse Linear Solvers. http://www.tau.ac.il/~stoledo/taucs

[49]

Erva Ulu, James Mccann, and Levent Burak Kara. 2017. Lightweight Structure Design under Force Location Uncertainty. ACM Trans. Graph. 36, 4, Article 158 (July 2017), 13 pages.

Digital Library

[50]

Nobuyuki Umetani and Bernd Bickel. 2018. Learning Three-Dimensional Flow for Interactive Aerodynamic Design. ACM Trans. Graph. 37, 4, Article 89 (July 2018), 10 pages.

Digital Library

[51]

Nobuyuki Umetani, Takeo Igarashi, and Niloy J. Mitra. 2012. Guided Exploration of Physically Valid Shapes for Furniture Design. ACM Trans. Graph. 31, 4, Article 86 (July 2012), 11 pages.

Digital Library

[52]

Mickeal Verschoor, Dan Casas, and Miguel A. Otaduy. 2020. Tactile Rendering Based on Skin Stress Optimization. ACM Trans. Graph. 39, 4, Article 90 (July 2020), 13 pages.

Digital Library

[53]

Tuanfeng Y. Wang, Tianjia Shao, Kai Fu, and Niloy J. Mitra. 2019. Learning an Intrinsic Garment Space for Interactive Authoring of Garment Animation. ACM Trans. Graph. 38, 6, Article 220 (Nov. 2019), 12 pages.

Digital Library

[54]

Clarisse Weischedel. 2012. A discrete geometric view on shear-deformable shell models.

[55]

Katja Wolff and Olga Sorkine-Hornung. 2019. Wallpaper Pattern Alignment along Garment Seams. ACM Trans. Graph. 38, 4, Article 62 (July 2019), 12 pages.

Digital Library

[56]

Jun-Hai Yong and Fuhua (Frank) Cheng. 2004. Geometric Hermite curves with minimum strain energy. Computer Aided Geometric Design 21, 3 (2004), 281 -- 301.

Digital Library

[57]

Haiming Zhao, Weiwei Xu, Kun Zhou, Yin Yang, Xiaogang Jin, and Hongzhi Wu. 2017. Stress-Constrained Thickness Optimization for Shell Object Fabrication. Computer Graphics Forum 36, 6 (2017), 368--380.

Digital Library

Cited By

Xie YWang XZhou XZhou Q(2025)Bidirectional Pattern Recognition and Prediction of Bending-Active Thin Sheets via Artificial Neural NetworksElectronics10.3390/electronics1403050314:3(503)Online publication date: 26-Jan-2025
https://doi.org/10.3390/electronics14030503
ZHANG XLUO DLI JLONG Y(2024)Experimental Research on the Mechanical Response of Insulating Laminated Glass Plates Under Single-Curved Cold BendingIndustrial Construction10.3724/j.gyjzG2112071454:7(159-165)Online publication date: 26-Sep-2024
https://doi.org/10.3724/j.gyjzG21120714
Rist FWang ZPellis DPalma MLiu DGrinspun EMichels D(2024)A Flexible Mold for Facade Panel FabricationACM Transactions on Graphics10.1145/368790643:6(1-16)Online publication date: 19-Dec-2024
https://dl.acm.org/doi/10.1145/3687906
Show More Cited By

Index Terms

Computational design of cold bent glass façades
1. Applied computing
  1. Physical sciences and engineering
    1. Engineering
      1. Computer-aided design
2. Computing methodologies
  1. Computer graphics
    1. Shape modeling
  2. Machine learning
    1. Learning paradigms
      1. Unsupervised learning
        Mixture modeling

Recommendations

Glass frit bonding: an universal technology for wafer level encapsulation and packaging

This paper reports on glass frit wafer bonding, which is a universally usable technology for wafer level encapsulation and packaging. After explaining the principle and the process flow of glass frit bonding, experimental results are shown. Glass frit ...
Inverse Design Tool for Asymmetrical Self-Rising Surfaces with Color Texture
SCF '20: Proceedings of the 5th Annual ACM Symposium on Computational Fabrication

4D printing encodes self-actuating deformation during the printing process, such that objects can be fabricated flat and then transformed into target 3D shapes. While many flattening algorithms have been introduced for 4D printing, a general method ...
Computational design of fabric formwork

We present an inverse design tool for fabric formwork - a process where flat panels are sewn together to form a fabric container for casting a plaster sculpture. Compared to 3D printing techniques, the benefit of fabric formwork is its properties of low-...

Comments

Information & Contributors

Information

Published In

cover image ACM Transactions on Graphics

ACM Transactions on Graphics Volume 39, Issue 6

December 2020

1605 pages

ISSN:0730-0301

EISSN:1557-7368

DOI:10.1145/3414685

Editor:
Karol Myszkowski
MPI Informatik

Issue’s Table of Contents

Copyright © 2020 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 27 November 2020

Published in TOG Volume 39, Issue 6

Permissions

Request permissions for this article.

Request Permissions

Check for updates

Author Tags

Qualifiers

Research-article

Funding Sources

H2020 Marie Sk?odowska-Curie Actions
King Abdullah University of Science and Technology
Austrian Science Fund
European Research Council

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

14
Total Citations
View Citations
413
Total Downloads

Downloads (Last 12 months)78
Downloads (Last 6 weeks)11

Reflects downloads up to 12 Feb 2025

Other Metrics

View Author Metrics

Citations

Cited By

Xie YWang XZhou XZhou Q(2025)Bidirectional Pattern Recognition and Prediction of Bending-Active Thin Sheets via Artificial Neural NetworksElectronics10.3390/electronics1403050314:3(503)Online publication date: 26-Jan-2025
https://doi.org/10.3390/electronics14030503
ZHANG XLUO DLI JLONG Y(2024)Experimental Research on the Mechanical Response of Insulating Laminated Glass Plates Under Single-Curved Cold BendingIndustrial Construction10.3724/j.gyjzG2112071454:7(159-165)Online publication date: 26-Sep-2024
https://doi.org/10.3724/j.gyjzG21120714
Rist FWang ZPellis DPalma MLiu DGrinspun EMichels D(2024)A Flexible Mold for Facade Panel FabricationACM Transactions on Graphics10.1145/368790643:6(1-16)Online publication date: 19-Dec-2024
https://dl.acm.org/doi/10.1145/3687906
Miki MMitchell T(2024)Alignment conditions for NURBS-based design of mixed tension-compression grid shellsACM Transactions on Graphics10.1145/365814243:4(1-19)Online publication date: 19-Jul-2024
https://dl.acm.org/doi/10.1145/3658142
Huang ZTozoni DGjoka AFerguson ZSchneider TPanozzo DZorin D(2024)Differentiable solver for time-dependent deformation problems with contactACM Transactions on Graphics10.1145/365764843:3(1-30)Online publication date: 26-Apr-2024
https://dl.acm.org/doi/10.1145/3657648
Gjoka AKnoop EBächer MZorin DPanozzo D(2024)Soft Pneumatic Actuator Design using Differentiable SimulationACM SIGGRAPH 2024 Conference Papers10.1145/3641519.3657467(1-11)Online publication date: 13-Jul-2024
https://dl.acm.org/doi/10.1145/3641519.3657467
Zhang XYang JMeng Z(2023)Mechanical behaviour of frame-supported insulating glass during cold bendingJournal of Building Engineering10.1016/j.jobe.2022.10572265(105722)Online publication date: Apr-2023
https://doi.org/10.1016/j.jobe.2022.105722
Rahimzadeh KLevelle EDouglas J(2023)(Not) pushing the envelope: achieving the world’s largest cold bent façade with computation and 3-dimensional framingGlass Structures & Engineering10.1007/s40940-023-00235-y8:4(495-512)Online publication date: 22-Sep-2023
https://doi.org/10.1007/s40940-023-00235-y
Ansari NSeidel HBabaei V(2022)Mixed integer neural inverse designACM Transactions on Graphics10.1145/3528223.353008341:4(1-14)Online publication date: 22-Jul-2022
https://dl.acm.org/doi/10.1145/3528223.3530083
Zhao HWillsey MZhu ANandi CTatlock ZSolomon JSchulz A(2022)Co-Optimization of Design and Fabrication Plans for CarpentryACM Transactions on Graphics10.1145/350849941:3(1-13)Online publication date: 9-Mar-2022
https://dl.acm.org/doi/10.1145/3508499
Show More Cited By

View Options

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Article

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Figures

Tables

Media

View Issue’s Table of Contents