Effect of sintering temperature on density,microstructure,and depth hardness of stellite-6 produced by material extrusion (MEX)

Abstract

Material Extrusion (MEX) offers an efficient and scalable route to near-net-shape parts while decoupling shape formation from densification. However, there is a distinct lack of systematic data regarding the sintering behavior and depth-resolved properties of MEX-processed Stellite-6, particularly when utilizing a fully thermal debinding route. This study quantifies how sintering temperature influences densification and the mechanical response of Stellite-6 fabricated by MEX with fully thermal debinding. Green bodies extruded from the filament were sintered at 1300, 1310, and 1320°C. Relative density, dimensional stability, microstructure, and through-thickness Vickers hardness (HV0.3) were evaluated. Density went up steadily with temperature as most of the interconnected pores closed and particle necks grew stronger. At 1320°C, however, microstructural heterogeneity increased and noticeable edge warpage compromised the dimensional stability of the printed parts. The 1310°C condition offered the best overall compromise, combining high densification and microstructural stability with a uniform hardness of ∼631 HV0.3. Selecting a sintering schedule centered at 1310°C therefore maximizes density while maintaining consistent microhardness across MEX-processed Stellite-6 components. Future perspectives include investigating the effects of isothermal hold duration and post-sintering hot isostatic pressing (HIP) to eliminate residual porosity and further enhance the mechanical performance.

Keywords

Material extrusion (MEX)sintering temperature stellite-6 relative density microstructure vickers hardness thermal debinding

Get full access to this article

View all access options for this article.

References

Ngo

Kashani

Imbalzano

, et al. Additive manufacturing (3D printing): a review of materials, methods, applications and challenges. Compos B Eng 2018; 143: 172–196.

Tosto

Tirillò

Sarasini

, et al. Fused deposition modeling parameter optimization for cost-effective metal part printing. Polymers (Basel) 2022; 14: 3264.

Cuan-Urquizo

Barocio

Tejada-Ortigoza

, et al. Characterization of the mechanical properties of FFF structures and materials: a review on the experimental, computational and theoretical approaches. Materials (Basel) 2019; 12: 95.

Jacob

Pejak Simunec

Kandjani

, et al. A review of fused filament fabrication of metal parts (metal FFF): current developments and future challenges. Technologies 2024; 12: 267.

Çevik

Kam

. A review study on mechanical properties of obtained products by FDM method and metal/polymer composite filament production. J Nanomater 2020; 2020: –9.

Jurisch

Studnitzky

Andersen

, et al. 3D Screen printing for the fabrication of small intricate Ti-6Al-4V parts. Powder Metall 2015; 58: 339–343.

Dey

Roan Eagle

Yodo

. A review on filament materials for fused filament fabrication. J Manuf Mater Process 2021; 5: 69.

Galantucci

Pellegrini

Guerra

, et al. 3D Printing of parts using metal extrusion: an overview of shaping debinding and sintering technology. Adv Technol Mater 2022; 47: 25–32.

Zhang

Kong

, et al. Influence of diamond parameters on microstructure and properties of copper-based diamond composites manufactured by Fused Deposition Modeling and Sintering (FDMS). J Alloys Compd 2023; 931: 167492.

10.

Buchanan

Gardner

. Metal 3D printing in construction: a review of methods, research, applications, opportunities and challenges. Eng Struct 2019; 180: 332–348.

11.

Bazarbay

Kurbanova

Absadykov

, et al. Investigation of the effect of thermal post-treatment on density and hardness of a green part printed with fff technology. J Chem Technol Metall 2022: 57(6).

12.

Emanuelli

Segata

Perina

, et al. Study of microstructure and mechanical properties of 17-4 PH stainless steel produced via binder jetting. Powder Metall 2023; 66: 377–386.

13.

Hasan

Mazid

Clegg

. The basics of stellites in machining perspective. Int J Eng Mater Manuf 2016; 1: 35–50.

14.

Pourentezari Zarch

Zamani

. Strength–wear trade-off in DLMD stellite 6–SiC coatings. Surf Eng 2026: 02670844261450434. doi:10.1177/02670844261450434

15.

Park

Jung

K-H

Kim

, et al. Microstructure of as-cast Co-Cr-Mo alloy prepared by investment casting. J Korean Phys Soc 2018; 72: 947–951.

16.

Endo

Nakayama

Sakamura

. Effect of sintering conditions on microstructures and mechanical properties of stellite 6 alloy fabricated by MIM process. J Jpn Soc Powder Powder Metall 2025; 72: S673–S678.

17.

Nurhudan

Supriadi

Whulanza

, et al. Additive manufacturing of metallic based on extrusion process: a review. J Manuf Process 2021; 66: 228–237.

18.

Liu

Wang

Lin

, et al. Creating metal parts by fused deposition modeling and sintering. Mater Lett 2020; 263: 127252.

19.

Ferro

Fabrizi

Elsayed

, et al. Creating IN718-high carbon steel bi-metallic parts by fused deposition modeling and sintering. Procedia Struct Integr 2023; 47: 535–544.

20.

De La Cruz

Alvaredo

Torralba

, et al. Material extrusion: a promising tool for processing CoCrMo alloy with excellent wear resistance for biomedical applications. Mater Des 2024; 244: 113089.

21.

Gülsoy

HÖ

Özgün

Bilketay

. Powder injection molding of Stellite 6 powder: sintering, microstructural and mechanical properties. Mater Sci Eng A 2016; 651: 914–924.

22.

Mostafaei

De Vecchis

Buckenmeyer

, et al. Microstructural evolution and resulting properties of differently sintered and heat-treated binder-jet 3D-printed Stellite 6. Mater Sci Eng C 2019; 102: 276–288.

23.

Sadaf

Cano

Gonzalez-Gutierrez

, et al. Influence of binder composition and material extrusion (MEX) parameters on the 3D printing of highly filled copper feedstocks. Polymers (Basel) 2022; 14: 4962.

24.

Mwema

Wambua

Bodunrin

, et al. Thermal fluctuations on the corrosion behaviour of 17-4PH stainless steel alloys fabricated via material extrusion additive manufacturing technique. Proc Inst Mech Eng Part L J Mater Des Appl 2025; 239: 746–759.

25.

German

. Sintering theory and practice. John Wiley & Sons, 1996.

26.

Rahaman

. Ceramic processing and sintering. CRC press, 2017.

27.

Aladejebi

Mitra

Singh

, et al. A review of the sintering technologies to accommodate contemporary raw materials blends for ironmaking. Ironmak Steelmak 2025: 03019233251357167.

28.

Rahimi

Zamani

. Development of a feedstock for additive manufacturing of 4605 steel compact by FDMS process. Trans Indian Inst Met 2022; 75: 3087–3093.

29.

Lin

Sanetrnik

Cho

, et al. Rheological and thermal debinding properties of blended elemental ti-6Al-4V powder injection molding feedstock. Powder Technol 2017; 311: 357–363.

30.

Withers

Bhadeshia

. Residual stress. Part 1–measurement techniques. Mater Sci Technol 2001; 17: 355–365.

31.

Callister

Jr Rethwisch

. Materials science and engineering: an introduction. John wiley & sons, 2020.

32.

Sridar

Jimenez

, et al. Effect of processing parameters on recrystallization during hot isostatic pressing of stellite-6 fabricated using Laser powder bed fusion technique. Materials (Basel) 2024; 17: 5500.