The effect of varying specimens’ printing angles to the bed surface on the tensile strength of 3D-printed 17-4PH stainless-steels via metal FFF additive manufacturing

[1] Gonzalez-Gutierrez J(2018)Additive manufacturing of metallic and ceramic components by the material extrusion of highly-filled polymers: a review and future perspectives Materials (Basel) 11 840-11

[2] Cano S(2019)Robust surface-engineered tape-cast and extrusion methods to fabricate electrically-conductive poly(vinylidene fluoride)/carbon nanotube filaments for corrosion-resistant 3D printing applications Sci. Rep. 9 9618-1327

[3] Schuschnigg S(2018)Shape deposition manufacturing of 316L parts via feedstock extrusion and green-state milling Manuf. Lett. 18 6-5

[4] Kukla C(2019)Fused filament fabrication, debinding and sintering as a low cost additive manufacturing method of 316L stainless steel Addit. Manuf. 30 100861-28

[5] Sapkota J(2019)Process porosity and mechanical performance of fused filament fabricated 316L stainless steel Rapid Prototyp. J. 25 1319-105

[6] Holzer C(2018)Material properties and shrinkage of 3D printing parts using ultrafuse stainless steel 316LX filament MATEC Web Conf. 249 1-120

[7] Almazrouei A(1995)Rapid prototyping of functional metallic parts Comput. Ind. 28 23-168

[8] Susantyoko RA(2002)Solid freeform fabrication of metal components using fused deposition of metals Mater. Des. 23 97-481

[9] Wu C-H(2018)3D printing conditions determination for feedstock used in fused filament fabrication (FFF) of 17–4PH stainless steel parts Metalurgija 57 117-803

[10] Mustafa I(2019)Tensile properties of sintered 17–4PH stainless steel fabricated by material extrusion additive manufacturing Mater. Lett. 248 165-203

[1] Gonzalez-Gutierrez J(2018)Additive manufacturing of metallic and ceramic components by the material extrusion of highly-filled polymers: a review and future perspectives Materials (Basel) 11 840-11

[2] Cano S(2019)Robust surface-engineered tape-cast and extrusion methods to fabricate electrically-conductive poly(vinylidene fluoride)/carbon nanotube filaments for corrosion-resistant 3D printing applications Sci. Rep. 9 9618-1327

[3] Schuschnigg S(2018)Shape deposition manufacturing of 316L parts via feedstock extrusion and green-state milling Manuf. Lett. 18 6-5

[4] Kukla C(2019)Fused filament fabrication, debinding and sintering as a low cost additive manufacturing method of 316L stainless steel Addit. Manuf. 30 100861-28

[5] Sapkota J(2019)Process porosity and mechanical performance of fused filament fabricated 316L stainless steel Rapid Prototyp. J. 25 1319-105

[6] Holzer C(2018)Material properties and shrinkage of 3D printing parts using ultrafuse stainless steel 316LX filament MATEC Web Conf. 249 1-120

[7] Almazrouei A(1995)Rapid prototyping of functional metallic parts Comput. Ind. 28 23-168

[8] Susantyoko RA(2002)Solid freeform fabrication of metal components using fused deposition of metals Mater. Des. 23 97-481

[9] Wu C-H(2018)3D printing conditions determination for feedstock used in fused filament fabrication (FFF) of 17–4PH stainless steel parts Metalurgija 57 117-803

[10] Mustafa I(2019)Tensile properties of sintered 17–4PH stainless steel fabricated by material extrusion additive manufacturing Mater. Lett. 248 165-203