Ondrej Stava
Bedrich Benes
Abstract
The use of 3D printing has rapidly expanded in the past couple of years. It is now possible to produce 3D-printed objects with exceptionally high fidelity and precision. However, although the quality of 3D printing has improved, both the time to print and the material costs have remained high. Moreover, there is no guarantee that a printed model is structurally sound. The printed product often does not survive cleaning, transportation, or handling, or it may even collapse under its own weight. We present a system that addresses this issue by providing automatic detection and correction of the problematic cases. The structural problems are detected by combining a lightweight structural analysis solver with 3D medial axis approximations. After areas with high structural stress are found, the model is corrected by combining three approaches: hollowing, thickening, and strut insertion. Both detection and correction steps are repeated until the problems have been eliminated. Our process is designed to create a model that is visually similar to the original model but possessing greater structural integrity.
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- Allaire, G., and Jouve, F. 2008. Minimum stress optimal design with the level set method. Engineering Analysis with Boundary Elements 32, 11, 909--918.Google Scholar
Cross Ref
- Allaire. 2002. A level-set method for shape optimization. Comptes Rendus Mathematique 334, 12, 1125--1130.Google Scholar
- Allaire, G. 2004. Structural optimization using sensitivity analysis and a level-set method. Journal of Computational Physics 194, 1, 363--393. Google ScholarDigital Library
- Andrews, J., Joshi, P., and Carr, N. 2011. A linear variational system for modelling from curves. Comput. Graph. Forum.Google Scholar
- Balasubramanian, R., Xu, L., Brook, P. D., Smith, J. R., and Matsuoka, Y. 2010. Human-guided grasp measures improve grasp robustness on physical robot. In ICRA, 2294--2301.Google Scholar
- Butcher, J. C. 2008. Numerical Methods for Ordinary Differential Equations. John Wiley and Sons, Ltd.Google Scholar
- Cohen, J., Varshney, A., Manocha, D., Turk, G., Weber, H., Agarwal, P., Brooks, F., and Wright, W. 1996. Simplification envelopes. In Proceedings of the 23rd annual conference on Computer graphics and interactive techniques, ACM, New York, NY, USA, SIGGRAPH '96, 119--128. Google ScholarDigital Library
- Dey, T. K., and Zhao, W. 2003. Approximating the medial axis from the voronoi diagram with a convergence guarantee. Algorithmica 38 (October), 179--200. Google ScholarDigital Library
- Engineering Handbook, 2011. Rapid Prototyping -- Processes. http://engineershandbook.com/RapidPrototyping/rpprocesses.htm.Google Scholar
- Fu, H., Cohen-Or, D., Dror, G., and Sheffer, A. 2008. Upright orientation of man-made objects. ACM Trans. Graph. 27 (August), 42:1--42:7. Google ScholarDigital Library
- Golub, G. H., and Welsch, J. H. 1967. Calculation of gauss quadrature rules. Tech. rep., Stanford, CA, USA. Google ScholarDigital Library
- Hart, J. C., Baker, B., and Michaelraj, J. 2003. Structural simulation of tree growth and response. The Visual Computer 19, 2--3, 151--163.Google ScholarCross Ref
- Haslinger, J., AND Mäkinen, R. A. E. 2003. Introduction to Shape Optimization: Theory, Approximation, and Computation. SIAM, Philadelphia. Google ScholarDigital Library
- Hornung, A., and Kobbelt, L. 2006. Robust reconstruction of watertight 3d models from non-uniformly sampled point clouds without normal information. In Proc. of Symposium on Geometry Processing, Eurographics Association, 41--50. Google ScholarDigital Library
- Hughes, T. J. R. 1987. The Finite Element Method: Linear Static and Dynamic Finite Element Analysis. Prentice-Hall.Google Scholar
- Jirasek, C., Prusinkiewicz, P., and Moulia, B. 2000. Integrating biomechanics into developmental plant models expressed using 1-systems. In Proc. Plant Biomechanics, 615--624.Google Scholar
- Kinoshita, H., Bäckström, L., Flanagan, J. R., and Johansson, R. S. 1997. Tangential torque effects on the control of grip forces when holding objects with a precision grip. Journal of Neurophysiology 78, 3, 1619--1630.Google ScholarCross Ref
- Liu, R., Burschka, D., and Hirzinger, G. 2007. On the way to water-tight mesh. In Proc. of ISPRS.Google Scholar
- Liu, L., Chambers, E. W., Letscher, D., and Ju, T. 2010. A simple and robust thinning algorithm on cell complexes. Comput. Graph. Forum 29, 7, 2253--2260.Google ScholarCross Ref
- Osher, S., and Sethian, J. A. 1988. Fronts propagating with curvature dependent speed. Journal of Computational Physics 79, 12--49. Google ScholarDigital Library
- Peng, J., Kristjansson, D., and Zorin, D. 2004. Interactive modeling of topologically complex geometric detail. In ACM SIGGRAPH 2004 Papers, ACM, New York, NY, USA, SIGGRAPH '04, 635--643. Google ScholarDigital Library
- Schmidt, R., and Singh, K. 2010. meshmixer: an interface for rapid mesh composition. In ACM SIGGRAPH 2010 Talks, SIGGRAPH '10, ACM, 6:1--6:1. Google ScholarDigital Library
- Shapeways, 2011. 3D printing in 4 simple steps. http://www.shapeways.com/about/how_does_it_work.Google Scholar
- Shapeways, 2011. Things to keep in mind when designing for 3D printing. http://www.shapeways.com/tutorials/things-to-keep-in-mind.Google Scholar
- Shewchuk, J. R. 2001. Delaunay refinement algorithms for triangular mesh generation. Computational Geometry: Theory and Applications 22, 1--3. Google ScholarDigital Library
- Si, H., 2011. Tetgen: A quality tetrahedral mesh generator and a 3D delaunay triangulator.Google Scholar
- Telea, A., and Jalba, A. 2011. Voxel-based assessment of printability of 3d shapes. In Proc. of Mathematical morphology and its applications to image and signal processing, SpringerVerlag, Berlin, Heidelberg, ISMM, 393--404. Google ScholarDigital Library
- von Mises, R. 1913. Mechanik der festen körper im plastisch-deformablen zustand. Nachrichten von der Gesellschaft der Wissenschaften zu Göttingen, Mathematisch-Physikalische Klasse 1913, 582--592.Google Scholar
- Whiting, E., Ochsendorf, J., and Durand, F. 2009. Procedural modeling of structurally-sound masonry buildings. ACM Trans. Graph. 28, 5, 112. Google ScholarDigital Library
- Z Corporation, 2011. Architectural Design Guide - Printing 3D Architectural Models. http://crl.ap.buffalo.edu/digitalworkshop/zcorp/pdfs/archdesguide.pdf.Google Scholar
Index Terms
Stress relief: improving structural strength of 3D printable objects
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