nach oben

Advances in Manufacturing

Erschienen in:

22.05.2019

A comprehensive review of extrusion-based additive manufacturing processes for rapid production of metallic and ceramic parts

verfasst von: Kedarnath Rane, Matteo Strano

Erschienen in: Advances in Manufacturing | Ausgabe 2/2019

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

The extrusion-based additive manufacturing (EAM) technique is recently being employed for rapid production of metals and ceramic components. This technique involves extruding the metal or ceramic material in solid powder form mixed with a binder (i.e., an expendable viscous fluid), which is removed from the part after 3D printing. These technologies rely on the large design freedom allowed and the cost efficiency advantage over alternative metal additive manufacturing processes that are based on high energy beams, such as laser or electron beams. The EAM of metals and ceramics is not yet widespread, but published scientific and technical literature on it is rapidly growing. However, this literature is still less extensive than that on the fused deposition modeling (FDM) of plastics or the selective laser melting (SLM) of metals. This paper aims at filling this gap. FDM and powder injection molding are identified as preceding or enabling technologies for EAM. This paper systematically reviews all aspects of the feedstock EAM processes used for production of complex-shaped parts. The unique characteristics and advantages of these processes are also discussed with respect to materials and process steps. In addition, the key process parameters are explained to illustrate the suitability of the EAM process for diverse application domains.

Vorheriger Artikel Multi-response optimization of Ti-6Al-4V turning operations using Taguchi-based grey relational analysis coupled with kernel principal component analysis

Nächster Artikel Machine auscultation: enabling machine diagnostics using convolutional neural networks and large-scale machine audio data

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

ISO/ASTM 52900:2015(E) Standard terminology for additive manufacturing. ASTM 2015

Deckers J, Vleugels J, Kruth JP (2014) Additive manufacturing of ceramics: a review. J Ceram Sci Tech 5(4):245–260

Frazier WE (2014) Metal additive manufacturing: a review. J Mater Eng Perform 23(6):1917–1928CrossRef

Turner BN, Gold SA (2015) A review of melt extrusion additive manufacturing processes: II. materials, dimensional accuracy, and surface roughness. Rapid Prototyp J 21(3):250–261CrossRef

Turner N, Strong B, Gold S (2014) A review of melt extrusion additive manufacturing processes: I. Process design and modeling. Rapid Prototyp J 20(3):192–204CrossRef

Karunakaran KP, Alain Bernard, Suryakumar S et al (2012) Rapid manufacturing of metallic objects. Rapid Prototyp J 18(4):264–280CrossRef

Lewis JA, Smay JE, Stuecker J et al (2006) Direct ink writing of three-dimensional ceramic structures. J Am Ceram Soc 89(12):3599–3609CrossRef

Gonzalez-Gutierrez J, Cano S, Schuschnigg S et al (2018) Additive manufacturing of metallic and ceramic components by the material extrusion of highly-filled polymers: a review and future perspectives. Materials 11(5):840. https://doi.org/10.3390/ma11050840 CrossRef

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

10.

Carneiro OS, Silva AF, Gomes R (2015) Fused deposition modeling with polypropylene. Mater Des 83(15):768–776CrossRef

11.

Tymrak BM, Kreiger M, Pearce JM (2014) Mechanical properties of components fabricated with open-source 3D printers under realistic environmental conditions. Mater Des 58:242–246CrossRef

12.

Bottini A, Boschetto L (2014) Accuracy prediction in fused deposition modeling. Int J Adv Manuf Technol 73(5–8):913–928

13.

Ning F, Cong W, Qiu J et al (2015) Additive manufacturing of carbon fiber reinforced thermoplastic composites using fused deposition modeling. Compos B Eng 80:369–378CrossRef

14.

Brünler R, Aibibu D, Wöltje M et al (2017) In silico modeling of structural and porosity properties of additive manufactured implants for regenerative medicine. Mater Sci Eng C 76:810–817CrossRef

15.

xjet3d.com, XJet’s system. Accessed on 06 Sept 2017

16.

Miyanaji H, Zhang S, Lassell A et al (2016) Process development of porcelain ceramic material with binder jetting process for dental applications. JOM 68(3):831–841CrossRef

17.

King WE, Anderson AT, Ferencz RM et al (2015) Laser powder bed fusion additive manufacturing of metals; physics, computational, and materials challenges. Appl Phys Rev 2(4):41304CrossRef

18.

Khoshnevis B, Zhang J (2015) Selective separation sintering (SSS) A new layer based additive manufacturing approach for metals and ceramics. In: AIAA SPACE conference and exposition

19.

Gallo D, Biamino S, Fino P et al (2017) An overview of additive manufacturing of titanium components by directed energy deposition: microstructure and mechanical properties. Appl Sci 7(9):883. https://doi.org/10.3390/app7090883 CrossRef

20.

Rane K, Cataldo S, Parenti P et al (2018) Rapid production of hollow SS316 profiles by extrusion based additive manufacturing. AIP Conf Proc 1960(1):140014. https://doi.org/10.1063/1.5035006 CrossRef

21.

Stavropoulos P, Foteinopoulos P (2018) Modelling of additive manufacturing processes: a review and classification. Manuf Rev 5(2):1–26

22.

Atzeni E, Salmi A (2012) Economics of additive manufacturing for end-usable metal parts. Int J Adv Manuf Technol 62(9–12):1147–1155CrossRef

23.

German RM (2008) PIM breaks the $1 bn barrier. Metal Powder Rep 63(3):8–10CrossRef

24.

Gonçalves A (2001) Metallic powder injection molding using low pressure. J Mater Process Technol 118(1–3):193–198CrossRef

25.

German RM, Bose A (1997) Injection molding of metals and ceramics. Princeton, Metals Powder Industries Federation

26.

Jabbari A, Abrinia K (2018) Developing thixo-extrusion process for additive manufacturing of metals in semi-solid state. J Manuf Process 35:664–671CrossRef

27.

Tseng JW, Hsu CK (1999) Cracking defect and porosity evolution during thermal debinding in ceramic injection molding. Ceram Int 25(5):461–466CrossRef

28.

Finke S, Feenstra FK (2002) Solid freeform fabrication by extrusion and deposition of semi-solid alloys. J Mater Sci 37(15):3101–3106CrossRef

29.

Luo J, Qi LH, Zhong SY et al (2012) Printing solder droplets for micro devices packages using pneumatic drop-on-demand (DoD) technique. J Mater Process Technol 212(10):2066–2073CrossRef

30.

Zhong SY, Qi LH, Luo J et al (2014) Effect of process parameters on copper droplet ejecting by pneumatic drop-on-demand technology. J Mater Process Technol 214(12):3089–3097CrossRef

31.

Zhang D, Qi L, Luo J et al (2017) Direct fabrication of unsupported inclined aluminum pillars based on uniform micro droplets deposition. Int J Mach Tools Manuf 116:18–24CrossRef

32.

Cesarano J (1998) A review of robocasting technology. In: MRS Proceedings 542:133. https://doi.org/10.1557/PROC-542-133

33.

Slots C, Jensen MB, Ditzel N et al (2017) Simple additive manufacturing of an osteoconductive ceramic using suspension melt extrusion. Dental Mater 43(9):198–208CrossRef

34.

Travitzky N, Bonet A, Dermeik B et al (2014) Additive manufacturing of ceramic-based materials. Adv Eng Mater 16:729–754CrossRef

35.

Houmard M, Fu Q, Genet M et al (2013) On the structural, mechanical, and biodegradation properties of HA/β-TCP robocast scaffolds. J Biomed Mater Res B Appl Biomater 101:1233–1242CrossRef

36.

Thomas A, Kolan KC, Leu MC et al (2017) Freeform extrusion fabrication of titanium fiber reinforced 13–93 bioactive glass scaffolds. J Mech Behav Biomed Mater 69:153–162CrossRef

37.

Wang J, Shaw LL, Cameron TB (2006) Solid freeform fabrication of permanent dental restorations via slurry micro-extrusion. J Am Ceram Soc 89(1):346–349CrossRef

38.

I. 3. Bioprinter, Accessed on 25 Sept 2017

39.

Li JP, De Wijn JR, Van Blitterswijk CA et al (2006) Porous Ti6Al4V scaffold directly fabricating by rapid prototyping: preparation and in vitro experiment. Biomaterials 27(8):1223–1235CrossRef

40.

Sercombe TB, Schaffer GB, Lucia (1999) Freeform fabrication of functional aluminium prototypes using powder metallurgy. J Mater Sci 34(17):4245–4251CrossRef

41.

Grida I, Evans JRG (2003) Extrusion freeforming of ceramics through fine nozzles. J Eur Ceram Soc 23(5):629–635CrossRef

42.

Bellini A, Shor L, Guceri SI (2005) New developments in fused deposition modeling of ceramics. Rapid Prototyp J 11(4):214–220CrossRef

43.

Lu X, Lee Y, Yang S et al (2008) Fabrication of electromagnetic crystals by extrusion freeforming. Metamaterials 2(1):36–44CrossRef

44.

Lu X, Lee Y, Yang S et al (2009) Fine lattice structures fabricated by extrusion freeforming: process variables. J Mater Process Technol 209(10):4654–4661CrossRef

45.

Lu X, Lee Y, Yang S et al (2010) Solvent-based paste extrusion solid freeforming. J Eur Ceram Soc 30(1):1–10CrossRef

46.

Jafari MA, Han W, Mohammadi F et al (2000) A novel system for fused deposition of advanced multiple ceramics. Rapid Prototyp J 6(3):161–175CrossRef

47.

Wu G, Langrana NA, Sadanji R et al (2002) Solid freeform fabrication of metal components using fused deposition of metals. Mater Des 23(1):97–105CrossRef

48.

Vaidyanathan R, Walish J, Lombardi JL et al (2000) The extrusion freeforming of functional ceramic prototypes. JOM 52(12):34–37CrossRef

49.

Kalita SJ, Bose S, Hosick HL et al (2003) Development of controlled porosity polymer-ceramic composite scaffolds via fused deposition modeling. Mater Sci Eng C 23(5):611–620CrossRef

50.

3devo.com, 3devo.com/next-filament-extruder/. Accessed on 13 Oct 2017

51.

The Virtual Foundry. www.thevirtualfoundry.com/showcase/m0mau80bklzxkr50voo7gkvrdqzs38. Accessed on 12 Oct 2017

52.

Li JB, Xie ZG, Zhang XH et al (2010) Study of metal powder extrusion and accumulating rapid prototyping. Key Eng Mater 443:81–86CrossRef

53.

Holshouser C, Newell C, Palas S et al (2013) Out of bounds additive manufacturing. Adv Mater Process 171(3):15–27

54.

Annoni M, Giberti H, Strano M (2016) Feasibility study of an extrusion-based direct metal additive manufacturing technique. Proc Manuf 5:916–927

55.

Ren LQ, Zhou XL, Song ZY et al (2017) Process parameter optimization of extrusion-based 3D metal printing utilizing PW-LDPE-SA binder system. Materials 10(3):305. https://doi.org/10.3390/ma10030305 CrossRef

56.

Gaub (2016) www.arburg.com/us/us/products-and-services/additive-manufacturing/freeformer-system. (Online). Accessed 04 June 2017

57.

D Rotman (2017) Director. www.technologyreview.com/s/604088/the-3-d-printer-that-could-finally-change-manufacturing/. (Film)

58.

Tay BY, Loh NH, Tor SB et al (2009) Characterisation of micro gears produced by micro powder injection moulding. Powder Technol 188(3):179–182CrossRef

59.

Rane KK, Date PP (2014) Rheological investigation of MIM feedstocks for reducing frictional effects during injection moulding. Adv Mater Res 966–967:196–205CrossRef

60.

A. F3049-14 (2014) Standard guide for characterizing properties of metal powders used for additive manufacturing processes. ASTM International, West Conshohocken, PA

61.

Thomas-Vielma P, Cervera A, Levenfeld B et al (2008) Production of alumina parts by powder injection molding with a binder system based on high density polyethylene. J Eur Ceram Soc 28(4):763–771CrossRef

62.

Kiyota Y (1989) Patent US4867943

63.

Kang H, Kitsomboonloha R, Jang J et al (2012) High-performance printed transistors realized using femtoliter gravure-printed sub-10 μm metallic nanoparticle patterns and highly uniform polymer dielectric and semiconductor layers. Adv Mater 24(22):3065–3069CrossRef

64.

Maleksaeedi S, Eng H, Wiria FE et al (2014) Property enhancement of 3D-printed alumina ceramics using vacuum infiltration. J Mater Process Technol 214(7):1301–1306CrossRef

65.

Asadi-Eydivand M, Solati-Hashjin M, Farzad A et al (2016) Effect of technical parameters on porous structure and strength of 3D printed calcium sulfate prototypes. Robot Comput Integr Manuf 37:57–67CrossRef

66.

Gaytan SM, Cadena MA, Karim H et al (2015) Fabrication of barium titanate by binder jetting additive manufacturing technology. Ceram Int 41(5):6610–6619CrossRef

67.

Farzadi A, Waran V, Solati-Hashjin M et al (2015) Effect of layer printing delay on mechanical properties and dimensional accuracy of 3D printed porous prototypes in bone tissue engineering. Ceram Int 41(7):8320–8330CrossRef

68.

Vitorino N, Freitas C, Ribeiro MJ et al (2014) Extrusion of ceramic emulsions: plastic behavior. Appl Clay Sci 101:315–319CrossRef

69.

Kono T, Horata A, Kondo T (1997) Development of titanium and titanium alloy by metal injection molding process. J Jpn Soc Powder Metall 44:985–992CrossRef

70.

Wen G, Cao P, Gabbitas B et al (2013) Development and design of binder systems for titanium metal injection molding: an overview. Metall Mater Trans A 44(3):1530–1547CrossRef

71.

Ahn S, Park SJ, Lee S et al (2009) Effect of powders and binders on material properties and molding parameters in iron and stainless steel powder injection molding process. Powder Technol 193(2):162–169CrossRef

72.

Levenfeld B, Varez A, Torralba JM (2002) Effect of residual carbon on the sintering process of M2 high speed steel parts obtained by a modified metal injection molding process. Metall Mater Trans A 33(6):1843–1851CrossRef

73.

Moballegh L, Morshedian J, Esfandeh M (2005) Copper injection molding using a thermoplastic binder based on paraffin wax. Mater Lett 59(22):2832–2837CrossRef

74.

Suri P, Atre SV, German RM et al (2003) Effect of mixing on the rheology and particle characteristics of tungsten-based powder injection molding feedstock. Mater Sci Eng A 356(1):337–344CrossRef

75.

Bose A, Schuh CA, Tobia JC et al (2018) Traditional and additive manufacturing of a new tungsten heavy alloy alternative. Int J Refract Metals Hard Mater 73:22–28CrossRef

76.

Merz L, Rath S, Piotter V et al (2002) Feedstock development for micro powder injection molding. Microsyst Technol 8(2–3):129–132CrossRef

77.

Samuel I, Lin E (2001) Near-net-shape forming of zirconia optical sleeves by ceramics injection molding. Ceram Int 27(2):205–214CrossRef

78.

Yang WW, Yang KY, Hon MH (2003) Effects of PEG molecular weights on rheological behavior of alumina injection molding feedstocks. Mater Chem Phys 78(2):416–424CrossRef

79.

Ani S, Muchtar SM, Muhamad A et al (2014) Binder removal via a two-stage debinding process for ceramic injection molding parts. Ceram Int 40(2):2819–2824CrossRef

80.

Burkhardt C, Freigassner P, Weber O et al (2016) Fused filament fabrication (FFF) of 316L green parts for the MIM process. In: Proceedings of the world PM2016 congress and exhibition, Hamburg, Germany, 9–13 Oct 2016

81.

www.mixer.co.uk/en/product/zx-sigma-mixer-extruder. U. Winkworth Mixer Co. Accessed 04 May 2017

82.

Hausnerová B (2011) Powder injection moulding—an alternative processing method for automotive items. In: new trends and development in automotive system engineering. InTech, pp 129–146

83.

Peng F, Vogt BD, Cakmak M (2018) Complex flow and temperature history during melt extrusion in material extrusion additive manufacturing. Addit Manuf 22:197–206CrossRef

84.

Northcutt LA, Orski SV, Migler KB et al (2018) Effect of processing conditions on crystallization kinetics during materials extrusion additive manufacturing. Polymer 154:182–187CrossRef

85.

Valkenaers H, Vogeler F, Voet A et al (2013) Screw extrusion based 3D printing, a novel additive manufacturing technology. In: International conference on competitive manufacturing (COMA)

86.

Tseng JW, Liu CY, Yen YK et al (2018) Screw extrusion-based additive manufacturing of PEEK. Mater Des 140:209–221CrossRef

87.

Pachauri P, Hamiuddin M (2015) Optimization of injection moulding process parameters in MIM for impact toughness of sintered parts. Int J Adv Mater Metall Eng 1:1–11

88.

Giberti H, Sbaglia L, Silvestri M (2017) Mechatronic design for an extrusion-based additive manufacturing machine. Machines 5(4):29. https://doi.org/10.3390/machines5040029 CrossRef

89.

Rishi O (2013) Feed rate effects in freeform filament extrusion. Dissertation, Rochester Institute of Technology

90.

Fiore E, Giberti H, Sbaglia L (2015) Dimensional synthesis of a 5-DoF parallel kinematic manipulator for a 3D printer. In: 16th international conference on research and education in mechatronics (REM), Bochun Germany, 18–20 Nov 2015

91.

Giberti H, Fiore E, Sbaglia L (2016) Kinematic synthesis of a new 3D printing solution. In: MATEC Web of conferences

92.

Anzalone GC, Zhang CL, Wijnen B et al (2013) A low-cost open-source metal 3-D printer. IEEE Access 1:803–810CrossRef

93.

Giberti H, Sbaglia L, Urgo M (2017) A path planning algorithm for industrial processes under velocity constraints with an application to additive manufacturing. J Manuf Syst 43:160–167CrossRef

94.

Monzón MD, Gibson I, Benítez AN et al (2013) Process and material behavior modeling for a new design of micro-additive fused deposition. Int J Adv Manuf Technol 67(9–12):2717–2726CrossRef

95.

Oliveira RVB, Soldi V, Fredel MC et al (2005) Ceramic injection molding: influence of specimen dimensions and temperature on solven debinding kinetics. J Mater Process Technol 160(2):213–220CrossRef

96.

Royer A, Barrière T, Gelin JC (2016) Development and characterization of a metal injection molding bio sourced Inconel 718 feedstock based on polyhydroxyalkanoates. Metals 6(4):89. https://doi.org/10.3390/met6040089 CrossRef

97.

Tandon R (2008) Metal injection moulding in encyclopedia of materials science and technology. Elsevier, Amsterdam, pp 5439–5442

98.

Boljanovic V (2010) Powder metallurgy, in metal shaping processes: casting and molding, particulate processing, deformation processes, metal removal. Industrial Press Inc, New York, pp 75–106

99.

Parenti P, Kuriakose S, Mussi V et al (2017) Green-state micromilling of AISI316L feedstock. In: World congress on micro and nano manufacturing, 27–30 Mar 2017

100.

Parenti P, Cataldo S, Annoni M (2018) Shape deposition manufacturing of 316L parts via feedstock extrusion and green-state milling. Manuf Lett 18:6–11CrossRef

101.

A. F3091/F3091M-14 (2014) Standard specification for powder bed fusion of plastic materials, ASTM International, West Conshohocken, PA

102.

A. F3122-14 (2014) Standard guide for evaluating mechanical properties of metal materials made via additive manufacturing processes, ASTM International, West Conshohocken, PA

103.

Komineas G, Foteinopoulos P, Papacharalampopoulos A et al (2018) Build time estimation models in thermal extrusion additive manufacturing processes. Proc Manuf 21:647–654

104.

Ghazanfari A, Li WB, Leu MC et al (2016) A novel extrusion-based additive manufacturing process for ceramic parts. In: 26th annual international solid freeform fabrication symposium

105.

Brenken B, Barocio E, Favaloro A et al (2019) Development and validation of extrusion deposition additive manufacturing process simulations. Addit Manuf 25:218–226CrossRef

106.

Singh S, Ramakrishna S, Singh R (2017) Material issues in additive manufacturing: a review. J Manuf Process 25:185–200CrossRef

107.

Faes M, Valkenaers H, Vogeler F et al (2015) Extrusion-based 3D printing of ceramic components. Proc CIRP 28:76–81CrossRef

108.

Bletzinger KU, Ramm E (2001) Structural optimization and form finding of light weight structures. Comput Struct 79(22–25):2053–2062CrossRef

109.

Gonzalez-Gutierrez J, Godec D, Guran R et al (2018) 3D printing conditions determination for feedstock used in fused filament fabrication (FFF) of 17-4PH stainless steel parts. Metalurgija 57:117–120

110.

Moritz T, Partsch U, Ziesche S et al (2014) Additive manufacturing of ceramic components. Mater Process Annu Rep 15:28–31

111.

Ghazanfari A, Li W, Leu M et al (2017) Mechanical characterization of parts produced by ceramic on-demand extrusion process. Int J Appl Ceram Technol 14(3):486–494CrossRef

112.

Li W, Ghazanfari A, McMillen D et al (2017) Fabricating ceramic components with water dissolvable support structures by the ceramic on-demand extrusion process. CIRP Ann Manuf Technol 66:225–228CrossRef

113.

Lieberwirth C, Harder A, Seitz H (2017) Extrusion based additive manufacturing of metals parts. J Mech Eng Autom 7:79–83

Titel: A comprehensive review of extrusion-based additive manufacturing processes for rapid production of metallic and ceramic parts
verfasst von: Kedarnath Rane
Matteo Strano
Publikationsdatum: 22.05.2019
Verlag: Shanghai University
Erschienen in: Advances in Manufacturing / Ausgabe 2/2019
Print ISSN: 2095-3127
Elektronische ISSN: 2195-3597
DOI: https://doi.org/10.1007/s40436-019-00253-6

Premium Partner

Marktübersichten

Die im Laufe eines Jahres in der „adhäsion“ veröffentlichten Marktübersichten helfen Anwendern verschiedenster Branchen, sich einen gezielten Überblick über Lieferantenangebote zu verschaffen.

Zur Marktübersicht

Springer Professional

Abstract

Bitte loggen Sie sich ein, um Zugang zu Ihrer Lizenz zu erhalten.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Weitere Artikel der Ausgabe 2/2019

Machine auscultation: enabling machine diagnostics using convolutional neural networks and large-scale machine audio data

Structural, ferromagnetic, and optical properties of Fe and Al co-doped ZnO diluted magnetic semiconductor nanoparticles synthesized under high magnetic field

Flow correction control with electromagnetically induced preform resting process

Effects of boron content on environmental embrittlement of ordered Ni3Fe alloys

Multi-response optimization of Ti-6Al-4V turning operations using Taguchi-based grey relational analysis coupled with kernel principal component analysis

Influence of die geometry on self-piercing riveting of aluminum alloy AA6061-T6 to mild steel SPFC340 sheets

Premium Partner

Marktübersichten