Research Article
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Year 2023, , 21 - 31, 31.03.2023
https://doi.org/10.17350/HJSE19030000287

Abstract

References

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  • Bolat Ç., Akgün İ.C. and Gökşenli A. Effects of particle size, bimodality and heat treatment on mechanical properties of pumice reinforced aluminum syntactic foams produced by cold chamber die casting, China Foundry, 18 (2021) 529-540.
  • Bolat Ç., Bilge G. and Gökşenli A. An investigation on the effect of heat treatment on the compression behavior of aluminum matrix syntactic foam fabricated by sandwich infiltration casting, Mat. Res., 24 (2) (2021).
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  • Ünal E., Karaca F. and Sarsılmaz F. Investigation of interface microstructure properties of AISI 316l /AISI 4140 steel couple welded by friction welding process, Journal of the Faculty of Engineering and Architecture of Gazi University, 34 (2) (2019) 701-708.
  • Mahdianikhotbesara A., Sehhat M.H. and Hadad M. Experimental study on micro-friction stir welding of dissimilar butt joints between Al 1050 and pure copper., Metallogr. Microstruct. Anal., 10 (2021) 458-473.
  • Annur D., Rochmanto F., Thaha Y.N., Kartika I., Dimyati A. and Supriadi S. Processing and characterization of porous titanium for orthopedic implant prepared by argon-atmospheric sintering and arc plasma sintering, Mat. Res., 24 (6) (2021).
  • Wang Z., Xu L., Peng J., Tang Z., Han Z. and Liu J. Effect of the microstructure and properties of graphite/copper composites fabricated by microwave sintering. J. Mater. Sci., 56 (2021) 9183-9195.
  • Nasiri S., Sadegh-Yazdi M., Mousavi S.M., Ziya-Shamami M. and Mostofi T.M. Repeated underwater explosive forming: Experimental investigation and numerical modeling based on coupled Eulerian–Lagrangian approach, Thin. Wall. Struct., 172 (2022).
  • Bhujangrao T., Veiga F., Penalva M., Costas A. and Ruiz C. (2022). Three-dimensional finite element modelling of sheet metal forming for the manufacture of pipe components: Symmetry considerations, Symmetry, 14 (2022) 228.
  • Ergene B. Simulation of the production of Inconel 718 and Ti6Al4V biomedical parts with different relative densities by selective laser melting (SLM) method, Journal of the Faculty of Engineering and Architecture of Gazi University, 37 (1) (2022) 469-484.
  • Ravikumar P., Desai C., Kushwah, S. and Mangrola M.H. A review article on FDM process parameters in 3D printing for composite materials, Mater. Today. Proc., 60 (3) (2022) 2162-2166.
  • Yoo S.Y., Kim S.K., Heo S.J., Koak J.Y. and Kim J.G. Dimensional accuracy of dental models for three-unit prostheses fabricated by various 3D printing Technologies, Materials, 14 (2021) 1550.
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  • Özen A., Abali B.E., Völlmecke C., Gerstel J. and Auhl D. Exploring the role of manufacturing parameters on microstructure and mechanical properties in fused deposition modeling (FDM) using PETG, Appl. Compos. Mater., 28 (2021) 1799-1828.
  • Karabeyoglu S.S., Eksi O., Yaman P. and Kucukyildirim B.O. Effects of infill pattern and density on wear performance of FDM-printed acrylonitrile-butadiene-styrene parts, J. Polym. Eng., 41 (2021) 854-862.
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  • Karabeyoglu S.S., Eksi O., Istif I. and Feratoglu K. Identification of tensile behaviour of polylactic acid parts manufactured by fused deposition modeling under heat-treated conditions using nonlinear autoregressive with exogenous and transfer function models, J. Polym. Eng., 42 (2022) 1004-1016.
  • Mercado-Colmenero J.M., La Rubia M.D., Mata-Garcia E., Rodriguez-Santiago M. and Martin-Doñate C. Experimental and numerical analysis for the mechanical characterization of PETG polymers manufactured with FDM technology under pure uniaxial compression stress states for architectural applications, Polymers, 12 (2020) 2202.
  • Srinivasan R., Nirmal Kumar, K., Jenish Ibrahim A., Anandu, K.V. and Gurudhevan R. Impact of fused deposition process parameter (infill pattern) on the strength of PETG part, Mater. Today. Proc., 27 (2) (2020) 1801-1805.
  • Sehhat M.H., Mahdianikhotbesara A. and Yadegari F. Impact of temperature and material variation on mechanical properties of parts fabricated with fused deposition modeling (FDM) additive manufacturing, Int. J. Adv. Manuf. Technol., 120 (2022) 4791-4801.
  • Nathaphan S. and Trutassanawin W. Effects of process parameters on compressive property of FDM with ABS, Rapid Prototyping J., 27 (5) (2021) 905-917.
  • Vyavahare S. and Kumar S. Numerical and experimental investigation of FDM fabricated re-entrant auxetic structures of ABS and PLA materials under compressive loading, Rapid Prototyping J., 27 (2) (2021) 223-244.
  • Algarni M. and Ghazali S. Comparative study of the sensitivity of PLA, ABS, PEEK, and PETG’s mechanical properties to FDM printing process parameters, Crystals, 11 (2021) 995.
  • Chokshi H., Shah D.B., Patel K.M. and Joshi S.J. Experimental investigations of process parameters on mechanical properties for PLA during processing in FDM, Adv. Mater. Process. Technol., (2021). 1-14.
  • Ergene B., Şekeroğlu İ., Bolat Ç, and Yalçın B. An experimental investigation on mechanical performances of 3D printed lightweight ABS pipes with different cellular wall thickness, J. Mech. Eng. Sci., 15 (2) (2021) 8169-8177.
  • Norani M.N.M., Abdollah M.F.B., Abdullah M.I.H.C., Amiruddin H., Ramli F.R. and Tamaldin N. 3D printing parameters of acrylonitrile butadiene styrene polymer for friction and wear analysis using response surface methodology, P I MECH ENG J-J ENG., 235 (2) (2021) 468-477.
  • Raheja K., Jain A., Sharma C., Rana R. and Lal R. Comparative Study of Tribological Parameters of 3D Printed ABS and PLA Materials. In: Singari, R.M., Mathiyazhagan, K., Kumar, H. (eds) Advances in Manufacturing and Industrial Engineering. Lecture Notes in Mechanical Engineering. (2021) Springer, Singapore
  • Phogat A., Chhabra D., Sindhu V. and Ahlawat A. Analysis of wear assessment of FDM printed specimens with PLA, multi-material and ABS via hybrid algorithms, Mater. Today., 62 (1) (2022) 37-43.
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  • Azadi M., Dadashi A., Dezianian S., Kianifar M., Torkaman S. and Chiyani M. High-cycle bending fatigue properties of additive-manufactured ABS and PLA polymers fabricated by fused deposition modeling 3D-printing, Forces in Mechanics, 3 (2021) 100016.
  • Magri A., Vanaei S., Shirimbayan M., Vaudreuil S. and Tchakhtchi A. An Investigation to Study the Effect of Process Parameters on the Strength and Fatigue Behavior of 3D-Printed PLA-Graphene, Polymers, 13 (19) (2021) 3218.
  • Basgul C., Yu T., MacDonald D.W., Siskey R., Marcolongo M. and Kurtz S.M. Does annealing improve the interlayer adhesion and structural integrity of FFF 3D printed PEEK lumbar spinal cages?, J Mech Behav Biomed Mater., 102 (2020) 103455.
  • Akhoundi B., Nabipour M., Hajami F. and Shakoori D. An Experimental Study of Nozzle Temperature and Heat Treatment (Annealing) Effects on Mechanical Properties of High-Temperature Polylactic Acid in Fused Deposition Modeling, Polym Eng Sci., 60 (2020) 979-987.
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  • Mishra K.P., Ponnusamy S. and Nallamilli, M.S.R. The influence of process parameters on the impact resistance of 3D printed PLA specimens under water-absorption and heat-treated conditions, Rapid Prototyp. J., 27 (6) (2021) 1108-1123.
  • Syrlybayev D., Zharylkassyn B., Seisekulova A., Perveen A. and Talamona D. Optimization of the Warpage of Fused Deposition Modeling Parts Using Finite Element Method, Polymers, 13 (2021) 3849.
  • Lu X., Chiumenti M., Cervera M., Tan H., Lin X. and Wang S. Warpage Analysis and Control of Thin-Walled Structures Manufactured by Laser Powder Bed Fusion, Metals, 11 (2021) 686.
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Simulation of Fused Deposition Modeling of Glass Fiber Reinforced ABS Impact Samples: The Effect of Fiber Ratio, Infill Rate, and Infill Pattern on Warpage and Residual Stresses

Year 2023, , 21 - 31, 31.03.2023
https://doi.org/10.17350/HJSE19030000287

Abstract

It is known that products made of polymer materials or especially polymer materials with glass fiber and carbon fiber are used in many different areas such as automotive, aerospace, and defense. At this point, studies in the literature have gained momentum due to the combination of fiber-reinforced polymer materials emerging as a result of technological developments and industrial demands, and the fused deposition modeling (FDM) method providing the production of parts in desired sizes and complexity. Residual stresses and distortions occurring in polymer-based composite parts produced with FDM are among the problems that should be minimized. In this study, the influences of fiber ratio (%10, %15, and %20), infill rate (%20, %50, and %80), and infill pattern (line, honeycomb, and triangle) on the residual stresses and warpages generating in impact test specimens produced from glass fiber reinforced ABS filaments by fused deposition modeling were tried to be determined with the Digimat 2021 program. As a result of the findings, it was determined that the distortion values decreased and the thermal residual stress values went up with the increase in fiber ratio and infill rate. In addition, it can be reported that the distortions that bring out as a result of the separation of the produced parts from the production platform are caused by the high deformations condensing at the lower corner points of the parts.

References

  • Mandloi P., Dhakar B., Pare V. and Manepatil S. Experimental investigation of wear properties of AA6061 + Al2O3 metal matrix composite fabricated by vacuum stir casting method, Mater. Today- Proc, 61 (1) (2022) 55-61.
  • Bolat Ç., Akgün İ.C. and Gökşenli A. Effects of particle size, bimodality and heat treatment on mechanical properties of pumice reinforced aluminum syntactic foams produced by cold chamber die casting, China Foundry, 18 (2021) 529-540.
  • Bolat Ç., Bilge G. and Gökşenli A. An investigation on the effect of heat treatment on the compression behavior of aluminum matrix syntactic foam fabricated by sandwich infiltration casting, Mat. Res., 24 (2) (2021).
  • Davis R., Singh A., Debnath K., Sabino R.M., Popat,K., Soares P., Keshri A.K. and Borgohain B. Enhanced micro-electric discharge machining-induced surface modification on biomedical Ti-6Al-4V alloy, ASME. J. Manuf. Sci. Eng., 144 (7) (2022).
  • Ergene B. and Bolat Ç. A review on the recent investigation trends in abrasive waterjet cutting and turning of hybrid composites, Sigma Journal of Engineering and Natural Sciences, 37 (3) (2019) 989-1016.
  • Ünal E., Karaca F. and Sarsılmaz F. Investigation of interface microstructure properties of AISI 316l /AISI 4140 steel couple welded by friction welding process, Journal of the Faculty of Engineering and Architecture of Gazi University, 34 (2) (2019) 701-708.
  • Mahdianikhotbesara A., Sehhat M.H. and Hadad M. Experimental study on micro-friction stir welding of dissimilar butt joints between Al 1050 and pure copper., Metallogr. Microstruct. Anal., 10 (2021) 458-473.
  • Annur D., Rochmanto F., Thaha Y.N., Kartika I., Dimyati A. and Supriadi S. Processing and characterization of porous titanium for orthopedic implant prepared by argon-atmospheric sintering and arc plasma sintering, Mat. Res., 24 (6) (2021).
  • Wang Z., Xu L., Peng J., Tang Z., Han Z. and Liu J. Effect of the microstructure and properties of graphite/copper composites fabricated by microwave sintering. J. Mater. Sci., 56 (2021) 9183-9195.
  • Nasiri S., Sadegh-Yazdi M., Mousavi S.M., Ziya-Shamami M. and Mostofi T.M. Repeated underwater explosive forming: Experimental investigation and numerical modeling based on coupled Eulerian–Lagrangian approach, Thin. Wall. Struct., 172 (2022).
  • Bhujangrao T., Veiga F., Penalva M., Costas A. and Ruiz C. (2022). Three-dimensional finite element modelling of sheet metal forming for the manufacture of pipe components: Symmetry considerations, Symmetry, 14 (2022) 228.
  • Ergene B. Simulation of the production of Inconel 718 and Ti6Al4V biomedical parts with different relative densities by selective laser melting (SLM) method, Journal of the Faculty of Engineering and Architecture of Gazi University, 37 (1) (2022) 469-484.
  • Ravikumar P., Desai C., Kushwah, S. and Mangrola M.H. A review article on FDM process parameters in 3D printing for composite materials, Mater. Today. Proc., 60 (3) (2022) 2162-2166.
  • Yoo S.Y., Kim S.K., Heo S.J., Koak J.Y. and Kim J.G. Dimensional accuracy of dental models for three-unit prostheses fabricated by various 3D printing Technologies, Materials, 14 (2021) 1550.
  • Liu Z., Wang Y. and Wu B. A critical review of fused deposition modeling 3D printing technology in manufacturing polylactic acid parts, Int. J. Adv. Manuf. Technol., 102 (2019) 2877-2889.
  • Kumar, S. and Kishor, B. Ultrasound Added Additive Manufacturing for Metals and Composites: Process and Control. In: Mavinkere Rangappa, S., Gupta, M.K., Siengchin, S., Song, Q. (eds) Additive and Subtractive Manufacturing of Composites. Springer Series in Advanced Manufacturing (2021) Springer, Singapore.
  • Zhang H., Huang T., Jiang Q., He L., Bismarck A. and Hu Q. Recent progress of 3D printed continuous fiber reinforced polymer composites based on fused deposition modeling: a review, J. Mater. Sci., 56 (2021) 12999-13022.
  • Carloni D., Zhang G. and Wu Y. Transparent alumina ceramics fabricated by 3D printing and vacuum sintering, J. Eur. Ceram. Soc., 41 (1) (2021) 781-791.
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  • Popescu D., Zapciu A., Amza C., Baciu F. and Marinescu M. FDM process parameters influence over the mechanical properties of polymer specimens: A review, Polymer Testing, 69 (2018) 157-166.
  • Syrlybayev D., Zharylkassyn B., Seisekulova A., Akhmetov M., Perveen A. and Talamona D. Optimisation of strength properties of FDM printed parts—A critical review, Polymers, 13 (2021) 1587.
  • Özen A., Abali B.E., Völlmecke C., Gerstel J. and Auhl D. Exploring the role of manufacturing parameters on microstructure and mechanical properties in fused deposition modeling (FDM) using PETG, Appl. Compos. Mater., 28 (2021) 1799-1828.
  • Karabeyoglu S.S., Eksi O., Yaman P. and Kucukyildirim B.O. Effects of infill pattern and density on wear performance of FDM-printed acrylonitrile-butadiene-styrene parts, J. Polym. Eng., 41 (2021) 854-862.
  • Ergene B., Atlıhan G. and Pinar A. Investigation of the effect of taper angle and boundary condition on natural frequency of the 3D printed PET-G beams, Int. J. Print. Technol. Digit. Ind., 6 (2022) 31-39.
  • Karabeyoglu S.S., Eksi O., Istif I. and Feratoglu K. Identification of tensile behaviour of polylactic acid parts manufactured by fused deposition modeling under heat-treated conditions using nonlinear autoregressive with exogenous and transfer function models, J. Polym. Eng., 42 (2022) 1004-1016.
  • Mercado-Colmenero J.M., La Rubia M.D., Mata-Garcia E., Rodriguez-Santiago M. and Martin-Doñate C. Experimental and numerical analysis for the mechanical characterization of PETG polymers manufactured with FDM technology under pure uniaxial compression stress states for architectural applications, Polymers, 12 (2020) 2202.
  • Srinivasan R., Nirmal Kumar, K., Jenish Ibrahim A., Anandu, K.V. and Gurudhevan R. Impact of fused deposition process parameter (infill pattern) on the strength of PETG part, Mater. Today. Proc., 27 (2) (2020) 1801-1805.
  • Sehhat M.H., Mahdianikhotbesara A. and Yadegari F. Impact of temperature and material variation on mechanical properties of parts fabricated with fused deposition modeling (FDM) additive manufacturing, Int. J. Adv. Manuf. Technol., 120 (2022) 4791-4801.
  • Nathaphan S. and Trutassanawin W. Effects of process parameters on compressive property of FDM with ABS, Rapid Prototyping J., 27 (5) (2021) 905-917.
  • Vyavahare S. and Kumar S. Numerical and experimental investigation of FDM fabricated re-entrant auxetic structures of ABS and PLA materials under compressive loading, Rapid Prototyping J., 27 (2) (2021) 223-244.
  • Algarni M. and Ghazali S. Comparative study of the sensitivity of PLA, ABS, PEEK, and PETG’s mechanical properties to FDM printing process parameters, Crystals, 11 (2021) 995.
  • Chokshi H., Shah D.B., Patel K.M. and Joshi S.J. Experimental investigations of process parameters on mechanical properties for PLA during processing in FDM, Adv. Mater. Process. Technol., (2021). 1-14.
  • Ergene B., Şekeroğlu İ., Bolat Ç, and Yalçın B. An experimental investigation on mechanical performances of 3D printed lightweight ABS pipes with different cellular wall thickness, J. Mech. Eng. Sci., 15 (2) (2021) 8169-8177.
  • Norani M.N.M., Abdollah M.F.B., Abdullah M.I.H.C., Amiruddin H., Ramli F.R. and Tamaldin N. 3D printing parameters of acrylonitrile butadiene styrene polymer for friction and wear analysis using response surface methodology, P I MECH ENG J-J ENG., 235 (2) (2021) 468-477.
  • Raheja K., Jain A., Sharma C., Rana R. and Lal R. Comparative Study of Tribological Parameters of 3D Printed ABS and PLA Materials. In: Singari, R.M., Mathiyazhagan, K., Kumar, H. (eds) Advances in Manufacturing and Industrial Engineering. Lecture Notes in Mechanical Engineering. (2021) Springer, Singapore
  • Phogat A., Chhabra D., Sindhu V. and Ahlawat A. Analysis of wear assessment of FDM printed specimens with PLA, multi-material and ABS via hybrid algorithms, Mater. Today., 62 (1) (2022) 37-43.
  • Ergene B. and Bolat Ç. An experimental study on the role of manufacturing parameters on the dry sliding wear performance of additively manufactured PETG, Int. Polym. Process., 37 (3) (2022) 255-270.
  • Safai L., Cuellar J.S., Smit G. and Zadpoor A.A. A review of the fatigue behavior of 3D printed polymers, Addit. Manuf., 28 (2019) 87-97.
  • Azadi M., Dadashi A., Dezianian S., Kianifar M., Torkaman S. and Chiyani M. High-cycle bending fatigue properties of additive-manufactured ABS and PLA polymers fabricated by fused deposition modeling 3D-printing, Forces in Mechanics, 3 (2021) 100016.
  • Magri A., Vanaei S., Shirimbayan M., Vaudreuil S. and Tchakhtchi A. An Investigation to Study the Effect of Process Parameters on the Strength and Fatigue Behavior of 3D-Printed PLA-Graphene, Polymers, 13 (19) (2021) 3218.
  • Basgul C., Yu T., MacDonald D.W., Siskey R., Marcolongo M. and Kurtz S.M. Does annealing improve the interlayer adhesion and structural integrity of FFF 3D printed PEEK lumbar spinal cages?, J Mech Behav Biomed Mater., 102 (2020) 103455.
  • Akhoundi B., Nabipour M., Hajami F. and Shakoori D. An Experimental Study of Nozzle Temperature and Heat Treatment (Annealing) Effects on Mechanical Properties of High-Temperature Polylactic Acid in Fused Deposition Modeling, Polym Eng Sci., 60 (2020) 979-987.
  • Kumar K.S., Soundararajan R., Shanthosh G., Saravanakumar P. and Ratteesh M. Augmenting effect of infill density and annealing on mechanical properties of PETG and CFPETG composites fabricated by FDM, Mater. Today, 45 (2) (2021) 2186-2191.
  • Mishra K.P., Ponnusamy S. and Nallamilli, M.S.R. The influence of process parameters on the impact resistance of 3D printed PLA specimens under water-absorption and heat-treated conditions, Rapid Prototyp. J., 27 (6) (2021) 1108-1123.
  • Syrlybayev D., Zharylkassyn B., Seisekulova A., Perveen A. and Talamona D. Optimization of the Warpage of Fused Deposition Modeling Parts Using Finite Element Method, Polymers, 13 (2021) 3849.
  • Lu X., Chiumenti M., Cervera M., Tan H., Lin X. and Wang S. Warpage Analysis and Control of Thin-Walled Structures Manufactured by Laser Powder Bed Fusion, Metals, 11 (2021) 686.
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There are 67 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Research Articles
Authors

Berkay Ergene 0000-0001-6145-1970

Çağın Bolat 0000-0002-4356-4696

Publication Date March 31, 2023
Submission Date September 26, 2022
Published in Issue Year 2023

Cite

Vancouver Ergene B, Bolat Ç. Simulation of Fused Deposition Modeling of Glass Fiber Reinforced ABS Impact Samples: The Effect of Fiber Ratio, Infill Rate, and Infill Pattern on Warpage and Residual Stresses. Hittite J Sci Eng. 2023;10(1):21-3.

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