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Abstract

This study investigates the effects of powder size and shape on the properties of metallic porous bodies fabricated by powder metallurgy, with a particular focus on filtration efficiency. High-energy ball milling was performed on spherical stainless steel powder using a planetary ball mill, with process variables including ball size and rotational speed. The milled powders were then fabricated into metallic porous bodies through compaction and sintering, followed by filtration tests. The analysis indicated that larger ball sizes led to coarser powder particles, and higher rotational speeds transformed the powder shape from plate-like to needle-like. Filters produced with needle-like powders exhibited more complex pore structures, resulting in higher filtration efficiency despite similar porosity. These findings demonstrate that powder shape significantly influences the filtration properties of metallic filters manufactured via powder metallurgy.

Keywords

316L stainless steel powder high-energy ball milling powder shape metallic porous body filtration

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References

Jha

Sekellick

Rubow

. Sintered metal hot gas filters. High Temp Gas Clean 1999; 2: 492.

. Dependence of filtration properties on stainless steel medium structure. Filtr Sep 1997; 34: 265–273.

Kim

Song

Choi

, et al. Fabrication and characterization of porous nickel membrane for high precision gas filter by in-situ reduction/sintering process. J Powder Mater 2009; 16: 262–267.

Bae

Ahn

Sung

, et al. Fabrication and permeability of stainless steel filter by using filler metal. J Korean Powder Metall Inst 2004; 11: 288–293.

Nakajima

. Fabrication, properties and application of porous metals with directional pores. Prog Mater Sci 2007; 52: 1091–1173.

Cui

Sun

, et al. Effect of powder particle size on the microscopic morphology and mechanical properties of 316L stainless steel hollow spheres. Granul Matter 2025; 27: 1–14.

Ayub

Khan

McCarthy

, et al. Investigating the morphology, hardness, and porosity of copper filters produced via hydraulic pressing. J Mater Res Technol 2022; 19: 208–219.

Kho

Bae

, et al. Planetary ball mill process in aspect of milling energy. J Powder Mater 2014; 21: 155–164.

Suryanarayana

. Mechanical alloying and milling. Prog Mater Sci 2001; 46: 1–184.

10.

Liang

Fan

, et al. The ball to powder ratio (BPR) dependent morphology and microstructure of tungsten powder refined by ball milling. Powder Technol 2018; 339: 256–263.

11.

Nouri

Chen

, et al. Synthesis of Ti–Sn–Nb alloy by powder metallurgy. Mater Sci Eng A 2008; 485: 562–570.

12.

Tien

Payatakes

. Advances in deep bed filtration. AIChE J 1979; 25: 737–759.

13.

Zamani

Maini

. Flow of dispersed particles through porous media – deep bed filtration. J Petr Sci Eng 2009; 69: 71–88.

14.

Griffiths

Mitevski

Vujkovac

, et al. The role of tortuosity in filtration efficiency: a general network model for filtration. J Membr Sci 2020; 598: 117664.

15.

Wang

Schiller

. Computational characterization of nonwoven fibrous media: i. Pore-network extraction and morphological analysis. Phys Rev Mater 2020; 4: 083803.

16.

Cho

Dodds

Santamarina

. Particle shape effects on packing density, stiffness, and strength: natural and crushed sands. J Geotech Geoenviron Eng 2006; 132: 591–602.

17.

Rousé

Fannin

Shuttle

. Influence of roundness on the void ratio and strength of uniform sand. Géotechnique 2008; 58: 227–231.

18.

Garcia

Akanji

Blunt

, et al. Numerical study of the effects of particle shape and polydispersity on permeability. Phys Rev E 2009; 80: 021304.

19.

Nouri

Sola

. Metal particle shape: a practical perspective. Met Powder Rep 2018; 73: 276–282.

20.

Kotan

. Microstructural evolution of 316L stainless steels with yttrium addition after mechanical milling and heat treatment. Mater Sci Eng A 2015; 647: 136–143.

21.

Esmaeilzadeh

Salimi

Zamani

, et al. Effects of milling time and temperature on phase evolution of AISI 316 stainless steel powder and subsequent sintering. J Alloys Compd 2018; 766: 341–348.

22.

Fang

Dahl

. Strain hardening and transformation mechanism of deformation-induced martensite transformation in metastable austenitic stainless steels. Mater Sci Eng A 1991; 141: 189–198.

23.

Olson

Cohen

. A general mechanism of martensitic nucleation: part I. General concepts and the FCC → HCP transformation. Metall Trans A 1976; 7: 1897–1904.

24.

Olson

Cohen

. A general mechanism of martensitic nucleation: part II. FCC → BCC and other martensitic transformations. Metall Trans A 1976; 7: 1905–1914.

25.

Olson

Cohen

. A general mechanism of martensitic nucleation: part III. Kinetics of martensitic nucleation. Metall Trans A 1976; 7: 1915–1923.

26.

Pourghahramani

Forssberg

. Microstructure characterization of mechanically activated hematite using XRD line broadening. Int J Miner Process 2006; 79: 106–119.

27.

Khelifi

Abdelhak

Boumaiza

, et al. Correlations between XRD peak broadening and elastic and plastic deformation for mild steel sheets under tensile loading. Mater Sci 2024; 30: 414–423.

28.

Purushotham

Krishna

. X-ray determination of crystallite size and effect of lattice strain on Debye–Waller factors of platinum nano powders. Bull Mater Sci 2013; 36: 973–976.

29.

Ali

Karunanithi

Prashanth

, et al. X-ray peak broadening on microstructure, and structural properties of titanium and Ti-6Al-4V alloys. Mater Today Proc 2020; 27: 2390–2393.

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Fabrication and filtration efficiency of porous sintered bodies using shape-controlled 316L stainless steel powders by high-energy ball milling

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