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The International Journal of Advanced Manufacturing Technology

Erschienen in:

13.03.2020 | ORIGINAL ARTICLE

Improving additive manufacturing performance by build orientation optimization

verfasst von: Marina A. Matos, Ana Maria A. C. Rocha, Ana I. Pereira

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 5-6/2020

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Abstract

Additive manufacturing (AM) is an emerging type of production technology to create three-dimensional objects layer-by-layer directly from a 3D CAD model. AM is being extensively used in several areas by engineers and designers. Build orientation is a critical issue in AM since it is associated with the part accuracy, the number of supports required and the processing time to produce the object. This paper presents an optimization approach to solve the part build orientation problem taking into account some characteristics or measures that can affect the accuracy of the part, namely the volumetric error, the support area, the staircase effect, the build time, the surface roughness and the surface quality. A global optimization method, the Electromagnetism-like algorithm, is used to solve the part build orientation problem.

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Canellidis V, Dedoussis V, Mantzouratos N, Sofianopoulou S (2006) Pre-processing methodology for optimizing stereolithography apparatus build performance. Comput Indust 57(5):424– 436

Moroni G, Syam WP, Petrò S (2015) Functionality-based part orientation for additive manufacturing. Procedia CIRP 36:217–222

Jiang J, Xu X, Stringer J (2018) Support structures for additive manufacturing: a review. J Manuf Mater Process 2(4):64

Hull CW (1984) Apparatus for production of three-dimensional objects by stereolithography. United States Patent, Appl., No. 638905, Filed

Kruth JP, Leu MC, Nakagawa T (1998) Progress in additive manufacturing and rapid prototyping. Cirp Ann 47(2):525– 540

Taufik M, Jain PK (2013) Role of build orientation in layered manufacturing: a review. Int J Manuf Technol Manag 27(1–3):47–73

Bikas H, Stavropoulos P, Chryssolouris G (2016) Additive manufacturing methods and modelling approaches: a critical review. Int J Adv Manuf Technol 83(1–4):389–405

Del Re F, Scherillo F, Contaldi V, Palumbo B, Squillace A, Corrado P, Di Petta P (2019) Mechanical properties characterisation of alsi10mg parts produced by laser powder bed fusion additive manufacturing. Int J Mater Res 110(5):436–446

Pereira S, Vaz A, Vicente L (2018) On the optimal object orientation in additive manufacturing. Int J Adv Manuf Technol 98(5-8):1685–1694

10.

Pandey P, Reddy NV, Dhande S (2007) Part deposition orientation studies in layered manufacturing. J Mater Process Technol 185(1–3):125–131

11.

Thrimurthulu K, Pandey PM, Reddy NV (2004) Optimum part deposition orientation in fused deposition modeling. Int J Mach Tools Manuf 44(6):585–594

12.

Wang WM, Zanni C, Kobbelt L (2016) Improved surface quality in 3d printing by optimizing the printing direction. Comput Graph Forum 35(2):59–70

13.

Alharbi N, van de Veen AJ, Wismeijer D, Osman RB (2019) Build angle and its influence on the flexure strength of stereolithography printed hybrid resin material. An in vitro study and a fractographic analysis. Mater Technol 34(1):12–17

14.

Alexander P, Allen S, Dutta D (1998) Part orientation and build cost determination in layered manufacturing. Comput Aided Des 30(5):343–356

15.

Brika SE, Zhao YF, Brochu M, Mezzetta J (2017) Multi-objective build orientation optimization for powder bed fusion by laser. J Manuf Sci Eng 139(11):111011

16.

Das P, Chandran R, Samant R, Anand S (2015) Optimum part build orientation in additive manufacturing for minimizing part errors and support structures. Procedia Manuf 1:343–354

17.

Frank D, Fadel G (1995) Expert system-based selection of the preferred direction of build for rapid prototyping processes. J Intell Manuf 6(5):339–345

18.

Lan PT, Chou SY, Chen LL, Gemmill D (1997) Determining fabrication orientations for rapid prototyping with stereolithography apparatus. Comput Aided Des 29(1):53–62

19.

Masood S, Rattanawong W, Iovenitti P (2003) A generic algorithm for a best part orientation system for complex parts in rapid prototyping. J Mater Process Technol 139(1–3):110–116

20.

Zhang Y, De Backer W, Harik R, Bernard A (2016) Build orientation determination for multi-material deposition additive manufacturing with continuous fibers. Procedia Cirp 50:414–419

21.

Birbil Şİ, Fang SC, Sheu RL (2004) On the convergence of a population-based global optimization algorithm. J Global Optim 30(2–3):301–318MathSciNetMATH

22.

Jaiswal P, Patel J, Rai R (2018) Build orientation optimization for additive manufacturing of functionally graded material objects. Int J Adv Manuf Technol 96(1–4):223–235

23.

Livesu M, Ellero S, Martínez J, Lefebvre S, Attene M (2017) From 3d models to 3d prints: an overview of the processing pipeline. Comput Graph Forum 36(2):537–564

24.

Jibin Z (2005) Determination of optimal build orientation based on satisfactory degree theory for rpt. In: Ninth International conference on computer aided design and computer graphics, 2005. 6–pp. IEEE

25.

Rocha AMAC, Pereira AI, Vaz AIF (2018) Build orientation optimization problem in additive manufacturing. In: International conference on computational science and its applications. Springer, pp 669–682

26.

Masood SH, Rattanawong W, Iovenitti P (2000) Part build orientations based on volumetric error in fused deposition modelling. Int J Adv Manuf Technol 16(3):162–168

27.

Kattethota G, Henderson M (1998) A visual tool to improve layered manufacturing part quality. In: Proceedings of solid freeform fabrication symposium, pp 327–334

28.

Zhang Y, Bernard A, Harik R, Karunakaran K (2017) Build orientation optimization for multi-part production in additive manufacturing. J Intell Manuf 28(6):1393–1407

29.

Ahn DK, Kwon SM, Lee SH (2008) Expression for surface roughness distribution of fdm processed parts. In: In: International Conference on smart manufacturing application, 2008. ICSMA 2008. IEEE, pp 490–493

30.

Byun HS, Lee KH (2006) Determination of optimal build direction in rapid prototyping with variable slicing. Int J Adv Manuf Technol 28(3–4):307

31.

Campbell RI, Martorelli M, Lee HS (2002) Surface roughness visualisation for rapid prototyping models. Comput Aided Des 34(10):717–725

32.

Canellidis V, Giannatsis J, Dedoussis V (2009) Genetic-algorithm-based multi-objective optimization of the build orientation in stereolithography. Int J Adv Manuf Technol 45(7–8):714–730

33.

Mason A (2006) Multi-axis hybrid rapid prototyping using fusion deposition modeling. Master’s thesis, Ryerson University Toronto, ON. Canada

34.

Mohan Pandey P, Venkata Reddy N, Dhande SG (2003) Slicing procedures in layered manufacturing: a review. Rapid Prototyp J 9(5):274–288

35.

Pandey PM, Reddy NV, Dhande SG (2003) Improvement of surface finish by staircase machining in fused deposition modeling. J Mater Process Technol 132(1–3):323–331

36.

Behnam N (2011) Surface roughness estimation for fdm systems. Master’s thesis Ryerson University, Toronto, Canada

37.

Pandey PM (2010) Rapid prototyping technologies, applications and part deposition planning. Retrieved October 15:550–555

38.

Xu F, Wong Y, Loh H, Fuh J, Miyazawa T (1997) Optimal orientation with variable slicing in stereolithography. Rapid Prototyp J 3(3):76–88

39.

Rocha AMAC, Silva A, Rocha JG (2015) A new competitive implementation of the electromagnetism-like algorithm for global optimization. In: International conference on computational science and its applications. Springer, pp 506–521

Titel: Improving additive manufacturing performance by build orientation optimization
verfasst von: Marina A. Matos
Ana Maria A. C. Rocha
Ana I. Pereira
Publikationsdatum: 13.03.2020
Verlag: Springer London
Erschienen in: The International Journal of Advanced Manufacturing Technology / Ausgabe 5-6/2020
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI: https://doi.org/10.1007/s00170-020-04942-6

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