Sage Journals: Discover world-class research

Abstract

Nickel-free high nitrogen austenitic stainless steel, with a composition according to ASTM F 2581, was produced by hot powder forging (HPF). To improve the sintering behavior and increase the density of this alloy, a biocompatible additive of Mn-11.5 wt% Si at 3, and 6 wt% was added to the alloying powder, and the effect of the additives on the physical and mechanical properties of the alloy was investigated. The structure of the specimens was examined by X-ray diffraction (XRD), metallography, optical microscopy, scanning electron microscopy (SEM) and transmission electron microscopy(TEM), selected area diffraction (SAD) and magnetometer. The densities of the samples were analyzed by the Archimedes and image analysis methods and the mechanical properties of the samples were determined by microhardness, hardness, compression and tensile tests. The XRD results demonstrate that the forged samples contain austenitic nanocrystalline and amorphous phases with no ferrite and martensitic phases in the structure. Densitometry proves that the sample with a 6 wt% additive consolidated to near 96% theoretical density. Hardness, microhardness, tensile and compression tests show that this alloy composition also has better mechanical properties than alloys containing 0 and 3 wt% additive. The results show that stainless steel 316L and forged nickel-free high nitrogen austenitic stainless steel behave similarly to soft magnetic materials, although the magnetic saturation of nickel-free steel is lower than that of 316L steel. This study proves that the alloy made by HPF has significantly better mechanical properties than conventional commercial 316L. The effect of the additive on the microstructure and other features is discussed in detail.

Keywords

Hot powder forging nickel-free austenitic stainless steel powder metallurgy medical-grade stainless steel elastic modulus

Get full access to this article

View all access options for this article.

References

Mohammed

Ishak

Aqida

, et al. Effects of heat input on microstructure, corrosion and mechanical characteristics of welded austenitic and duplex stainless steels: a review. Metals (Basel) 2017; 7: 39.

Tangestani

Hadianfard

. Hydroxyapatite/titania nanocomposite coating on nickel-free austenitic stainless steel. Surf Coatings Technol 2021; 409: 126849.

Chen

Thouas

. Metallic implant biomaterials. Mater Sci Eng R Reports 2015; 87: 1–57.

Salahinejad

Hadianfard

Ghaffari

, et al. Compositional homogeneity in a medical-grade stainless steel sintered with a Mn-Si additive. Mater Sci Eng C 2012; 32: 2215–2219.

Salahinejad

Hadianfard

Ghaffari

, et al. Fabrication of nanostructured medical-grade stainless steel by mechanical alloying and subsequent liquid-phase sintering. Metall Mater Trans A 2012; 43: 2994–2998.

Talha

Behera

Sinha

. A review on nickel-free nitrogen containing austenitic stainless steels for biomedical applications. Mater Sci Eng C 2013; 33: 3563–3575.

Patnaik

Maity

Kumar

. Status of nickel free stainless steel in biomedical field: A review of last 10 years and what else can be done. Mater Today Proc 2020; 26: 638–643.

Sumita

Hanawa

Teoh

. Development of nitrogen-containing nickel-free austenitic stainless steels for metallic biomaterials. Mater Sci Eng C 2004; 24: 753–760.

Heidari

Tangestani

Hadeianfard

, et al. Effect of fabrication method on the structure and properties of a nanostructured nickel-free stainless steel. Adv Powder Technol 2020; 7: 3408–3419.

10.

Ali

Rani

Majdi

, et al. An efficient approach for nitrogen diffusion and surface nitriding of boron-titanium modified stainless steel alloy for biomedical applications. Metals (Basel) 2019; 9: 755.

11.

Matsuno

Yokoyama

Watari

, et al. Biocompatibility and osteogenesis of refractory metal implants, titanium, hafnium, niobium, tantalum and rhenium. Biomaterials 2001; 22: 1253–1262.

12.

Ngai

Peng

, et al. Microstructure and properties of porous high-N Ni-free austenitic stainless steel fabricated by powder metallurgical route. Materials (Basel) 2018; 11: 1058.

13.

Fang

Paramore

Sun

, et al. Powder metallurgy of titanium–past, present, and future. Int Mater Rev 2018; 63: 407–459.

14.

Wang

M-C

. Properties of high density powder forged iron based alloy. Powder Metall 1994; 37: 201–205.

15.

Yamanaka

Mori

Chiba

. Mechanical properties of as-forged Ni-free Co-29Cr-6Mo alloys with ultrafine-grained microstructure. Mater Sci Eng A 2011; 528: 5961–5966.

16.

Klar

Samal

. Powder metallurgy stainless steels: processing, microstructures, and properties. ASM international 2007, B-ASM-019.

17.

German

(1984) Powder metallurgy science. Met Powder Ind Fed 105 Coll Rd E, Princeton, N J 08540, U S A, 1984 279.

18.

Leo

JRO

Barroso

Fitzpatrick

, et al. Microstructure, tensile and creep properties of an austenitic ODS 316L steel. Mater Sci Eng A 2019; 749: 158–165.

19.

Javanbakht

Salahinejad

Hadianfard

. The effect of sintering temperature on the structure and mechanical properties of medical-grade powder metallurgy stainless steels. Powder Technol 2016; 289: 37–43.

20.

Javanbakht

Hadianfard

Salahinejad

. Microstructure and mechanical properties of a new group of nanocrystalline medical-grade stainless steels prepared by powder metallurgy. J Alloys Compd 2015; 624: 17–21.

21.

scholar (2).

22.

Salahinejad

Hadianfard

Ghaffari

, et al. Liquid-phase sintering of medical-grade P558 stainless steel using a new biocompatible eutectic additive. Mater Lett 2012; 74: 209–212.

23.

Dekhil

Alleg

Sunol

, et al. X-ray diffraction and Mössbauer spectrometry studies of the mechanically alloyed Fe-6P-1.7 C powders. Adv Powder Technol 2009; 20: 593–597.

24.

Salahinejad

Hadianfard

Ghaffari

, et al. Microstructural characterization of medical-grade stainless steel powders prepared by mechanical alloying and subsequent annealing. Adv Powder Technol 2013; 24: 605–608.

25.

Salahinejad

Amini

Hadianfard

. Structural evolution during mechanical alloying of stainless steels under nitrogen. Powder Technol 2012; 215: 247–253.

26.

Raghavan

. Effect of manganese on the stability of austenite in Fe-Cr-Ni alloys. Metall Mater Trans A 1995; 26: 237–242.

27.

Vander Voort

Lampman

Sanders

, et al. ASM handbook. Metallography and microstructures. 9th ed. 2004, pp. 40002–44073.

28.

Fontana

. Corrosion engineering. Pearson: Tata McGraw-Hill Education, 2005.

29.

Kunčická

Kocich

Lowe

. Advances in metals and alloys for joint replacement. Prog Mater Sci 2017; 88: 232–280.

30.

Kraus

Moszner

Fischerauer

, et al. Biodegradable Fe-based alloys for use in osteosynthesis: outcome of an in vivo study after 52 weeks. Acta Biomater 2014; 10: 3346–3353.

31.

Hermawan

Purnama

Dube

, et al. Fe-Mn alloys for metallic biodegradable stents: degradation and cell viability studies. Acta Biomater 2010; 6: 1852–1860.

32.

Yusop

Bakir

Shaharom

, et al. Porous biodegradable metals for hard tissue scaffolds: a review. Int J Biomater 2012; 2012: 1–10.

33.

Matassi

Botti

Sirleo

, et al. Porous metal for orthopedics implants. Clin Cases Miner Bone Metab 2013; 10: 111.

34.

Arifvianto

Zhou

. Fabrication of metallic biomedical scaffolds with the space holder method: a review. Materials (Basel) 2014; 7: 3588–3622.

35.

Čapek

Vojtěch

Oborná

. Microstructural and mechanical properties of biodegradable iron foam prepared by powder metallurgy. Mater Des 2015; 83: 468–482.

36.

Hench

Polak

. Third-generation biomedical materials. Science (80-) 2002; 295: 1014–1017.

37.

Salahinejad

Amini

Bajestani

, et al. Microstructural and hardness evolution of mechanically alloyed Fe-Cr-Mn-N powders. J Alloys Compd 2010; 497: 369–372.

38.

Rho

J-Y

Kuhn-Spearing

Zioupos

. Mechanical properties and the hierarchical structure of bone. Med Eng Phys 1998; 20: 92–102.

39.

Moszner

Sologubenko

Schinhammer

, et al. Precipitation hardening of biodegradable Fe-Mn-Pd alloys. Acta Mater 2011; 59: 981–991.

40.

Payerle

Team

Payerle

, et al. Scholar (3). Ann. Tour. Res. 2015; 3: 45.

41.

Kezrane

Guittoum

Hemmous

, et al. Elaboration, microstructure, and magnetic properties of nanocrystalline Fe 90 Ni 10 powders. J Supercond Nov Magn 2015; 28: 2473–2481.

42.

Tanhaei

Gheisari

Alavi Zaree

. Effect of cold rolling on the microstructural, magnetic, mechanical, and corrosion properties of AISI 316L austenitic stainless steel. Int J Miner Metall Mater 2018; 25: 630–640.

43.

Mondal

Basumallick

Chattopadhyay

. Effect of isothermal treatments on the magnetic behavior of nanocrystalline Cu–Ni–Fe alloy prepared by mechanical alloying. J Magn Magn Mater 2007; 309: 290–294.

44.

Chen

, et al. Recent development for preparation processes of Sm2Fe17N x powders with high magnetic properties. Chinese J Mater Res 2022; 36: 321–331.

45.

Abuchenari

Moradi

. The effect of Cu-substitution on the microstructure and magnetic properties of Fe-15% Ni alloy prepared by mechanical alloying. J Compos Compd 2019; 1: 10–15.

46.

Zaara

Khitouni

Escoda

, et al. Microstructural and magnetic behavior of nanocrystalline Fe-12Ni-16B-2Si alloy synthesis and characterization. Metals (Basel) 2021; 11: 1679.

47.

Amini

Shokrollahi

Salahinejad

, et al. Microstructural, thermal and magnetic properties of amorphous/nanocrystalline FeCrMnN alloys prepared by mechanical alloying and subsequent heat treatment. J Alloys Compd 2009; 480: 617–624.

48.

Kalita

MPC

Perumal

Srinivasan

. Structure and magnetic properties of nanocrystalline Fe75Si25 powders prepared by mechanical alloying. J Magn Magn Mater 2008; 320: 2780–2783.

49.

Huang

Logé

. A review of dynamic recrystallization phenomena in metallic materials. Mater Des 2016; 111: 548–574.

50.

Xie

, et al. Hot deformation characteristics and dynamic recrystallization mechanism of GH4730 Ni-based superalloy. J Alloys Compd 2019; 785: 918–924.

51.

Hong

Shi

Sheng

, et al. Effects of hot-working parameters on microstructural evolution of high nitrogen austenitic stainless steel. Mater Des 2011; 32: 3711–3717.

52.

Mapelli

Mombelli

Gruttadauria

, et al. Performance of stainless steel foams produced by infiltration casting techniques. J Mater Process Technol 2013; 213: 1846–1854.

53.

Gibson

Ashby

. Cellular solids: structure and properties. Cambridge, UK: Cambridge university press, 1999.

54.

Ramakrishnan

Arunachalam

. Effective elastic moduli of porous ceramic materials. J Am Ceram Soc 1993; 76: 2745–2752.

55.

Chawla

Deng

. Microstructure and mechanical behavior of porous sintered steels. Mater Sci Eng A 2005; 390: 98–112.

56.

Chavoshi

Jiang

Wang

, et al. Density-based constitutive modelling of P/M FGH96 for powder forging. Int J Mech Sci 2018; 138: 110–121.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.57 MB

Microstructure,mechanical and magnetic properties of a nickel-free austenitic stainless steel fabricated by hot powder forging

Abstract

Keywords

Get full access to this article

References

Supplementary Material