Machined Surface Quality of Pre-Sintered Hardenable PM Steel

Thawatchai Khantisitthiporn; Monnapas Morakotjinda; Bhanu Vetayanugul; Ruangdaj Tongsri

doi:10.4028/www.scientific.net/KEM.659.335

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 659Machined Surface Quality of Pre-Sintered...

Machined Surface Quality of Pre-Sintered Hardenable PM Steel

Abstract:

The benefit of pre-sintered machining is to avoid machining difficulty of sintered parts especially hardenable PM steels. Pre-sintering treatments of green PM part at temperatures lower than the normal sintering temperature of 1120 °C result in green strength improvement high enough for machining. In this study, the influences of various pre-sintering temperatures and several machining conditions on machined surface quality of pre-sintered PM samples were investigated. The pre-sintered samples were machined by a turning process using a carbide cutting insert with varied cutting speeds at a fixed feed rate and depth of cut without cutting lubricant. Chromium alloyed PM steel (Astaloy^® CrM) powder samples with (0.5 wt. %C) and without graphite (0 wt. % C) additions mixed with 1 wt. % of zinc stearate were prepared as green parts by cold compaction in a cylindrical die with diameter of 30 mm. Green density was about 7.00 g/cm³ and height of each sample was controlled by hydraulic pressure and powder weight of 80 g/sample. The green samples were treated by pre-sintering treatment before machining testing. Surface quality of each machined sample was evaluated by average surface roughness and surface texture by SEM analysis and the appearance of outlet edge breakout. The experimental results revealed that the pre-sintered samples with graphite addition showed better surface quality in terms of surface roughness and surface texture and small outlet edge breakout appearance. Moreover, at high pre-sintering temperatures of 900 and 1,000°C, the samples showed similar average surface roughness under the same turning conditions. The obtained surface textures were better than those of the samples pre-sintered at 700 and 800°C. The outlet edge breakout could not be found in the graphite-added samples pre-sintering at 1,000°C.

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Periodical:

Key Engineering Materials (Volume 659)

Pages:

335-339

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.659.335

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Online since:

August 2015

Authors:

Thawatchai Khantisitthiporn*, Monnapas Morakotjinda, Bhanu Vetayanugul, Ruangdaj Tongsri

Keywords:

Powder Metallurgy (PM), Pre-Sintered Machining, Pre-Sintering, Sintered Hardenable PM Steel

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References

[1] A. Fujiki, Present state and future prospects of powder metallurgy parts for automotive applications, Mater. Chem. Phys. 67 (2001) 298-306.

DOI: 10.1016/s0254-0584(00)00455-7

Google Scholar

[2] E. Robert-Perron, C. Blais, Y. Thomas, S. Pelletier, M. Dionne, An integrated approach to the characterization of powder metallurgy components performance during green machining, Mater. Sci. Eng., A402 (2005) 325-334.

DOI: 10.1016/j.msea.2005.05.019

Google Scholar

[3] O. Andersson, H. Thordenberg, S. Berg, Machining of High Strength PM Steels, PM2004 (2004).

Google Scholar

[4] S. Moghaddam, H. Farhangi, M. Ghambari, N. Solimanjad, Effect of sinter hardening on mechanical properties of Astaloy CrM powder metallurgy steel, Micro & Nano Letters. 7 (2012) 955-958.

DOI: 10.1049/mnl.2012.0641

Google Scholar

[5] Y. Yu, Thermodynamic and Kinetic Behaviours of Astaloy CrM, Höganäs AB, SE-263 83 Höganäs, Sweden.

Google Scholar

[6] ASM Handbook, Vol. 7, Powder Metal Technologies and Applications, ASM International, (1998).

Google Scholar

[7] A. Davala, R.J. Causton, S.H. Luk and F. G. Hanejko, Productivity enhancement through improved machinability materials, SAE, Inc., (1999).

DOI: 10.4271/1999-01-0339

Google Scholar

[8] M. Gagne, F. Chagnon, Machining sinter-hardenable PM materials, Metal Powder Report, 54 (1999) 46.

DOI: 10.1016/s0026-0657(99)93008-4

Google Scholar

[9] F. Chanon, L. Tremblay, S. St-Laurent, M. Gagne, Improving green strength to enable green machining, SAE, Inc., (1999).

DOI: 10.4271/1999-01-0337

Google Scholar