Geometry extraction from GCODE files destined for 3D printers
Wojciech Sobieski
University of Warmia and MazuryResearch fields:
• applications and development of numerical methods of mechanics
• investigations on the spatial structure of granular porous media
• investigations on fluid flows through porous media
• investigations on dynamics of fluidized beds
• investigations on the cavitation phenomenon in hydraulic systems
• investigations on water hammer in water rams
• investigations on bifurcation phenomena in flow systems
• investigations on heat diffusion in heterogeneous materials
• sensitivity analysis of mathematical models
https://orcid.org/0000-0003-1434-5520
Wojsciech Kiński
Abstrakt
The paper presents a method of conversion of GCODE files designed for additive manufacturing in 3D printers to a format which may be conveniently visualized. In the investigations three different 3D models were created: a) shell model (a casing); b) solid model (a gear); c) model with curvilinear elements (a screw). All these models were converted to GCODE files. Next the reverse engineering was applied and GCODE files were converted to points sets. These points represent particular locations of the print head. In the developed algorithm the linear interpolation was added to obtain intermediate points between locations of the print head for longer sections. The final part shows an attempt of applying Poisson Surface Reconstruction in order to obtain the original geometry. The main motivation to develop a new software resulted from the observation that sometimes the original solid model is no longer available, while there is a need to change some geometry details or settings before production stage.
Słowa kluczowe:
GCODE, STL, additive manufacturing, 3D printers, reverse engineeringBibliografia
Baronio G., Harran S., Signoroni A. 2016. A Critical Analysis of a Hand Orthosis Reverse Engineering and 3D Printing Process. Applied Bionics and Biomechanics, Vol. 2016, Article ID 8347478, 7 p. Google Scholar
Baumann F., Bugdayci H., Grunert J., Keller F., Roller D. 2016. Influence of slicing tools on quality of 3D printed parts. Computer-Aided Design & Applications, Vol. 13(1), 14-31. Google Scholar
Baumann F.W., Schuermann M., Odefey U., Pfeil M. 2017. From GCODE to STL: Reconstruct Models from 3D Printing as a Service. IOP Conf. Series: Materials Science and Engineering, Vol. 280, 012033. Google Scholar
Dúbravčík M., Kender Š. 2012. Application of reverse engineering techniques in mechanics system services. Procedia Engineering, Vol. 48, 96-104. Google Scholar
Eslami A.M. 2017. Integrating Reverse Engineering and 3D Printing for the Manufacturing Process. American Society for Engineering Education, Paper ID #18869. Google Scholar
GNU Fortran Home Page [on-line]. 2018. URL:https://gcc.gnu.org/fortran/ (available at October 18, 2018). Google Scholar
Godoi F.C., Prakash S., Bhandari B.R. 2016. 3D printing technologies applied for food design: Status and prospects. Journal of Food Engineering, Vol. 179, 44-54. Google Scholar
Guerrero-de-Miera A., Espinosa M.M., Domínguez M. 2015. Bricking: A new slicing method to reduce warping. Procedia Engineering, Vol. 132, 126-131. Google Scholar
Habrat W. 2007. Obsługa i programowanie obrabiarek CNC. Poradnik operatora. Wydawnictwo KaBe, Krosno 2007. Google Scholar
Hangge P., Pershad Y., Witting A.A., Albadawi H., Oklu R. 2018. Three-dimensional (3D) printing and its applications for aortic diseases. Cardiovascular Diagnosis and Therapy, Vol. 8, 19-25. Google Scholar
Hu J. 2017. Study on STL-Based Slicing Process for 3d Printing. Proceedings of the 28th Annual International, Solid Freeform Fabrication Symposium – An Additive Manufacturing Conference. Austin TX, August 7-9, 11 p. Google Scholar
ISO 6983-1:2009 Automation systems and integration - Numerical control of machines -- Program format and definitions of address words - Part 1: Data format for positioning, line motion and contouring control systems. URL: https://www.iso.org/standard/34608.html (available at October 18, 2018). Google Scholar
jView [on-line], 2020. URL: http://www.jtronics.de/software/jview-simple-g-code-viewer/ (available at April 1, 2020). Google Scholar
Kazhdan M., Bolitho M., Hoppe H. 2006. Poisson surface reconstruction. Proceedings of the 4th Eurographics Symposium on Geometry Processing, Sardinia, Italy, 1-10. Google Scholar
Kramer T.R., Proctor F.M., Messina E. 2000. The NIST RS274NGC Interpreter - Version 3. NISTIR 6556, August 17, 121 p. Google Scholar
Lorensen W. E., Cline H. E. 1987. Marching cubes: a high resolution 3D surface construction algorithm. ACM SIGGRAPH Computer Graphics, Vol. 21 (4), 163-169. Google Scholar
Mathur R. 2016. 3D Printing in Architecture. International Journal of Innovative Science, Engineering & Technology, Vol. 3(7), 583-591. Google Scholar
MatterControl Home Page [on-line]. 2019. URL: https://www.matterhackers.com/ (available at April 10, 2019). Google Scholar
MeshLab Home Page [on-line]. 2019. URL: http://www.meshlab.net/ (available at April 10, 2019). Google Scholar
NC Viewer [on-line], 2020. URL: https://ncviewer.com/ (available at April 11, 2020). Google Scholar
Norlander R. 2017. Make it Complete: Surface Reconstruction Aided by Geometric Primitives. October 23, 75 p. Google Scholar
ParaView Home Page [on-line]. 2019. URL: https://www.paraview.org/ (available at April 10, 2019). Google Scholar
Parra-Cabrera C., Achille C., Kuhn S., Ameloot R. 2018. 3D printing in chemical engineering and catalytic technology: structured catalysts, mixers and reactors. Chemical Society Reviews. Vol. 1. Google Scholar
Pitayachaval P., Sanklong N., Thongrak A. 2018. A Review of 3D Food Printing Technology. MATEC Web of Conferences 213, 01012. Google Scholar
Shahi B.S. 2016. Advanced Manufacturing Techniques (3D Printing). International Journal of Mechanical And Production Engineering, Vol. 4(4), 16-23. Google Scholar
Shatornaya A.M., Chislova M.M., Drozdetskaya M.A., Ptuhina I.S. 2017. Efficiency of 3D printers in Civil Engineering. Construction of Unique Buildings and Structures, Vol. 9(60), 22-30. Google Scholar
Szebényi G., Czigány T., Magyar B., Karger-Kocsis J. 2017. 3D printing-assisted interphase engineering of polymer composites: Concept and feasibility. eXPRESS Polymer Letters, Vol.11(7), 525-530. Google Scholar
Tappa K, Jammalamadaka U., Ballard D.H., Bruno T, Israel M.R., Vemula H., Meacham J.M., Mills D.K., Woodard P.K., Weisman J.A. 2017. Medication eluting devices for the field of OBGYN (MEDOBGYN): 3D printed biodegradable hormone eluting constructs, a proof of concept study. PLoSONE 12(8): e0182929, August 2017. Google Scholar
Tay Y.W.D., Panda B., Paul S.C., Mohamed N.A.N., Tan M.J., Leong K.F. 2017. 3D printing trends in building and construction industry: a review. Virtual and Physical Prototyping. Google Scholar
Topçu O., Taşcıoğlu Y., Ünver H.Ö. 2011. A Method for Slicing CAD Models in Binary STL Format. 6th International Advanced Technologies Symposium (IATS’11), 16-18 May 2011, Elazığ, Turkey. Google Scholar
VTK – The Visualization Toolkit [on-line]. URL: https://www.vtk.org/ (available at April 10, 2019). Google Scholar
Wang W., Chao H., Tong J., Yang Z., Tong X., Li H., Liu X., Liuy L. 2014. Saliency-Preserving Slicing Optimization for Effective 3D Printing. COMPUTER GRAPHICS forum, Vol. 33(5), 1-12 . Google Scholar
Xu Y., Wu X., Guo X., Kong B., Zhang M., Qian X., Mi S., Sun W. 2016.The Boom in 3D-Printed Sensor Technology. Sensors, Vol. 17, 37 p. Google Scholar
University of Warmia and Mazury
<p> <span style="font-size: small;"><u>Research fields</u>:</span></p> <p>• applications and development of numerical methods of mechanics<br> • investigations on the spatial structure of granular porous media<br> • investigations on fluid flows through porous media<br> • investigations on dynamics of fluidized beds<br> • investigations on the cavitation phenomenon in hydraulic systems<br> • investigations on water hammer in water rams<br> • investigations on bifurcation phenomena in flow systems<br> • investigations on heat diffusion in heterogeneous materials<br> • sensitivity analysis of mathematical models</p> Polska
https://orcid.org/0000-0003-1434-5520
Research fields:
• applications and development of numerical methods of mechanics
• investigations on the spatial structure of granular porous media
• investigations on fluid flows through porous media
• investigations on dynamics of fluidized beds
• investigations on the cavitation phenomenon in hydraulic systems
• investigations on water hammer in water rams
• investigations on bifurcation phenomena in flow systems
• investigations on heat diffusion in heterogeneous materials
• sensitivity analysis of mathematical models
