Study on the interaction characteristics of acrylonitrile butadiene styrene and UV laser

• Autorzy: Son Seungik , Lee Dongkyoung

Identyfikatory

DOI

10.1007/s43452-020-00072-8

• Języki publikacji: EN

Abstrakty

EN

3D printing technology is currently used in various fields. Precision is also becoming more important as the usage of the 3D printing increases. However, the precision of the 3D printing is still low due to limitations of manufacturing methods. Especially, the surface roughness and quality are inconsistent. While the post-treatment is necessary, there are no systematic post-treatment methods. Thus, using the laser for the post-treatment of 3D printing would be a good option because it has many advantages for precision engineering. To be used for the post-treatment process, it is essential to understand the interaction characteristics between the laser and the 3D printing materials. Therefore, this study uses an UV pulsed laser and the acrylonitrile butadiene styrene (ABS), which is the most popular material for 3D printing, to understand the interaction characteristics. Furthermore, the effect of surface roughness on the interaction characteristics is also studied. The ABS specimens are prepared by an acetone fumigation technique and CNC milling. The laser is applied by varing laser pulse energy (50–340 μJ) on the ABS specimens. As the surface roughness decreases, it is confirmed that laser and ABS interaction have a certain pattern. For the specimen prepared by the acetone fumigation technique, Heat Affected Zone decreases with decreasing the laser pulse energy. The specimen prepared by end milling requires higher laser ablation threshold.

Słowa kluczowe

EN

surface roughness; laser pulse energy; post-processing; UV laser; ABS; interaction characteristics

PL

chropowatość powierzchni; obróbka końcowa; impuls laserowy

• Wydawca: Springer ; Wrocław University of Science and Technology
• Czasopismo: Archives of Civil and Mechanical Engineering
• Rocznik: 2020
• Tom: Vol. 20, no. 3
• Strony: 155--166
• Opis fizyczny: Bibliogr. 32 poz., rys., wykr.

Twórcy

autor

Son Seungik

• Department of Mechanical and Automotive Engineering, Kongju National University, Cheonan 31080, Korea

autor

Lee Dongkyoung

• Department of Mechanical and Automotive Engineering, Kongju National University, Cheonan 31080, Korea

Bibliografia

• [1] Choi J-W, Kim H-C. 3D printing technologies-a review. J Korean Soc Manuf Process Eng. 2015;14(3):1–8.
• [2] Moon SK, et al. Application of 3D printing technology for designing light-weight unmanned aerial vehicle wing structures. Int J Prec Eng Manuf Green Technol. 2014;1(3):223–8.
• [3] Ahn D-G, Yang D-Y. Principle of rapid prototyping and its trends. J Korean Soc Prec Eng. 2005;22(10):7–16.
• [4] Azari A, Nikzad S. The evolution of rapid prototyping in dentistry: a review. Rapid Prototyp J. 2009;15(3):216–25.
• [5] Kim GB, et al. Three-dimensional printing: basic principles and applications in medicine and radiology. Korean J Radiol. 2016;17(2):182–97.
• [6] Ibrahim D, et al. Dimensional error of selective laser sintering, three-dimensional printing and PolyJet™ models in the reproduction of mandibular anatomy. J Cranio Maxillofac Surg. 2009;37(3):167–73.
• [7] Hopkinson N, Majewski C, Zarringhalam H. Quantifying the degree of particle melt in Selective Laser Sintering®. CIRP Ann. 2009;58(1):197–200.
• [8] Jo K-H, et al. A study of post-processing methods for improving the tightness of a part fabricated by fused deposition modeling. Int J Prec Eng Manuf. 2016;17(11):1541–6.
• [9] Jeong HB, Suk HL. A study on the optimum time of acetone FUMIGATION using ABS Material of 3d Printer. Daejeon: Chungnam National University; 2016.
• [10] Park K-T. Degradation of acrylonitrile-butadiene-styrene in supercritical n-haxane, acetone. Seoul: Hanyang University Graduated School; 2007.
• [11] Lee D. Investigation of physical phenomena and cutting efficiency for laser cutting on anode for Li-Ion batteries. Appl Sci. 2018;8(2):266.
• [12] Lee D, Oh B, Suk J. The effect of compactness on laser cutting of cathode for lithium-ion batteries using continuous fiber laser. Appl Sci. 2019;9(1):205.
• [13] Lee D, Seo Y, Pyo S. Effect of laser speed on cutting characteristics of cement-based materials. Materials. 2018;11(7):1055.
• [14] Lee D, Ahn S. Investigation of laser cutting width of LiCoO2 coated aluminum for lithium-ion batteries. Appl Sci. 2017;7(9):914.
• [15] Lee D, Mazumder J. Effects of momentum transfer on sizing of current collectors for lithium-ion batteries during laser cutting. Opt Laser Technol. 2018;99:315–25.
• [16] Lee D, et al. Three dimensional simulation of high speed remote laser cutting of cathode for lithium-ion batteries. J Laser Appl. 2016;28(3):032010.
• [17] Lee D, et al. Parameter optimization for high speed remote laser cutting of electrodes for lithium-ion batteries. J Laser Appl. 2016;28(2):022006.
• [18] Lee D, et al. High speed remote laser cutting of electrodes for lithium-ion batteries: anode. J Power Sour. 2013;240:368–80.
• [19] Lee D, et al. Computational and experimental studies of laser cutting of the current collectors for lithium-ion batteries. J Power Sour. 2012;210:327–38.
• [20] Lee D, Pyo S. Experimental investigation of multi-mode fiber laser cutting of cement mortar. Materials. 2018;11(2):278.
• [21] Seo Y, Lee D, Pyo S. High-power fiber laser cutting for 50-mmthick cement-based materials. Materials. 2020;13(5):1113.
• [22] Seo Y, Lee D, Pyo S. Microstructural characteristics of cementbased materials fabricated using multi-mode fiber laser. Materials. 2020;13(3):546.
• [23] Lee D. Understanding of BeCu interaction characteristics with a variation of ns laser-pulse duration. Materials. 2018;11(8):1423.
• [24] Lee D. Experimental investigation of laser ablation characteristics on nickel-coated beryllium copper. Metals. 2018;8(4):211.
• [25] Lee D. Picosecond IR pulsed laser drilling of copper-coated glass/epoxy composite. IEEE Trans Comp Pack Manuf Technol. 2017;7(12):2066–72.
• [26] Lee D, et al. Application of laser spot cutting on spring contact probe for semiconductor package inspection. Opt Laser Technol. 2017;97:90–6.
• [27] Sancaktar E, Lu H. The effects of excimer laser irradiation at 248 nm on the surface mass loss and thermal properties of PS, ABS, PA6, and PC polymers. J Appl Polym Sci. 2006;99(3):1024–37.
• [28] Wei M-K, Yang H. Cumulative heat effect in excimer laser ablation of polymer PC and ABS. Int J Adv Manuf Technol. 2003;21(12):1029–34.
• [29] Kreutz E, et al. Processing of polymer surfaces by laser radiation. Nucl Instrum Methods Phys Res Sect B. 1995;105(1–4):245–9.
• [30] Hage E, et al. Crystallization behavior of PBT/ABS polimer blends. J Appl Polym Sci. 1999;71(3):423–30.
• [31] Baek DK, Ko TJ, Kim HS. Optimization of feedrate in a face milling operation using a surface roughness model. Int J Mach Tools Manuf. 2001;41(3):451–62.
• [32] Zhang JZ, Chen JC, Kirby ED. Surface roughness optimization in an end-milling operation using the Taguchi design method. J Mater Process Technol. 2007;184(1–3):233–9.

Uwagi

PL

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021)