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EFFECT OF SEVERE PLASTIC DEFORMATION ON STRUCTURE AND PROPERTIES OF AUSTENITIC AISI 316 GRADE STEEL

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EFFECT OF SEVERE PLASTIC DEFORMATION ON STRUCTURE AND PROPERTIES OF AUSTENITIC AISI 316 GRADE STEEL

Ladislav KANDERa, Miroslav GREGERb

aMATERIÁLOVÝ A METALURGICKÝ VÝZKUM, s.r.o., Ostrava, Czech Republic, EU ladislav.kander@mmvyzkum.cz

bVSB-Technical University of Ostrava, Ostrava,Czech Republic, EU, miroslav.greger@vsb.cz

Abstrakt

The article presents results of investigation of structure and properties of austenitic steel grade AISI 316 after application of Equal Channel Angular Pressing (ECAP) at the temperature of approx. 290C. The ECAP method leads to significant improvement of strength of investigated material. Investigation of structure was made by combination of TEM and FEG SEM together with EBSD. Statistic evaluation of angular disorientation and of size of grains/sub-grains was also made with use of electron diffraction (EBSD) in combination with scanning electron microscope FEG SEM Philips. It was proven that the ECAP method enables obtaining of ultra fine-grained austenitic structure. It was established with use of the EBSD technique that after 8 passes through the ECAP die the sub-grains with misorientation angles smaller than 10 formed less than 20% of the final structure. Average size of austenitic grains with high-angle boundaries after 8 passes was approx. 0.1m.

Keywords: AISI 316 grade steel, ECAP technology,mechanical and fatigue properties, grain size

1. INTRODUCTION

The ECAP method makes it possible to obtain the grain size of several hundreds of nanometres. Materials with sub-micron size of sub-grains/grains (d = 0.1-1 m) are usually classified as ultra fine-grained materials.

The ECAP method was so far unsuccessful at attempts of obtaining nanometric materials, i.e. materials with grain size under 0.1m. Characterisation of the fraction of sub-grains formed by recovery and grains separated by high-angle boundaries, which are formed by re-crystallisation, is very important for understanding the mechanisms of materials structure evolution at application of methods of extreme plastic deformation. It is well known a positive influence of ECAP technology on final material properties namely non ferrous metals but steel as well. However not many works is focused on achieved fatigue properties after that special treatment. This paper wants to contribute to knowledge distribution about austenitic stainless steel AISI 316 low cycle fatigue behaviour under ECAP.

2. MATERIAL, EXPERIMENTAL TECHNIGUE

A series of samples made of austenitic stainless steel AISI 316 was processed by the ECAP technology.

Basic chemical composition is given in the Table 1 and mechanical properties in the Table 2. The samples were manufactured with the following dimensions:  12 mm, length 60 mm. They were pushed through the ECAP matrix by 2 to 8 passed passes [1]. Matrix had channel diameter 12 mm and angle 105 o. Pressure in the matrix varied around approx. 740 MPa. Temperature of extrusion varied from room temperature up to 280 oC. After extrusion material was taken from the samples for metallographic testing and testing bars were manufactured for testing of mechanical properties. In order to expand the existing findings the testing bars were exposed to intensive magnetic field and impact of magnetic field on change of mechanical properties was investigated by tensile test. The sample was after eight passes subjected to structural analysis. Ten samples were determined for investigation of influence of the ECAP technology on fatigue properties.

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Individual samples were subjected to different number of passes: 3 pieces had 4 passes, 4 pieces had 5 passes and 3 pieces had 6 passes. Test samples for testing of low-cycle fatigue had diameter of the measured part 5 mm and overall length 55.

Tab. 1. Basic chemical composition of the steel (weight %)

C Mn Si P S Cu Ni Cr Mo

0.03 1.64 0.18 0.011 0.007 0.06 12.5 17.6 2.4

The low cycle fatigue tests were carried out in strain amplitude control regime on servohydraulic testing machine MTS 100 kN. During the each test hysteresis loops were recorded to calculate elastic and plastic portion of deformation amplitude.

Tab. 2. Mechanical properties of the steel AISI 316 –room temperature, as received condition

3. RESULTS, DISCUSSION Structure

Structures were analysed from the viewpoint of the course of strengthening and restoring processes. Fig. 1 documents deformed sub-structure of the steel AISI 316 after ECAP deformation by 4 to 8. Metallic matrix contained sub-grains of uneven size. Size of sub-grains was in most cases smaller than 0.1 m, only exceptionally some sub-grains/grains of the size of approx. 0.5 m were observed. Density of dislocations in metallic matrix was very high, presence of particles of precipitate was not found. In cases when neighbouring grains showed approximately identical diffraction contrast, it can be expected that angle of disorientation is only several degrees, while in case of significant changes of contrast rather high angular disorientation is probable. Fig. 2 documents a diffraction pattern, which was obtained from the area with diameter of approx.

1 m. Occurrence of discontinuous circles and at the same time azimuthal blurring of diffraction traces evidences the fact that big amount of fine sub-grains/grains with more or less different crystallographic orientation was present in the investigated area. Austenitic matrix often contained deformation bands, which were formed during the ECAP deformation, see Figures 1 and 2b. Deformation bands in austenitic steels can be formed by irregularly overlapping tiered errors, deformation twins or -martensite. These deformation bands are formed along octahedral planes { 111 } of austenitic matrix. It was proved with use of electron microscopy that in majority of cases these are deformation twins, nevertheless, presence of distinct stretching of reflections intensity („streaking") in directions { 111 } * proves frequent occurrence of crystallographic defects in these formations [2,3]. Width of deformation bands was very variable. In some areas intersecting systems of deformation bands occurred, which were formed at several planes of the type {

Steel grade

E GPa

Rp0.2 MPa

Rm MPa

A

% Z

% KV

J

AISI 316 216 330 625 45 76 90

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111 }, see Figures 2b and 2c. Points of intersection of deformation bands generally represent preferential points for formation of particles of '- martensite. However, electron diffraction analysis did not confirm occurrence of '- martensite in these areas [4,5]. Occurrence of '- martensite in investigated sample was not confirmed even by X-ray diffraction analysis. Deflection (deformation) of deformation bands was in many cases quite distinctly visible in pictures in light field. This evidences the fact that deformation bands formed during the ECAP deformation were further deformed during next passes. Sub-grains with high density of dislocations were usually aligned along deformation bands.

Fig. 1. Structure of steel AISI 316 after ECAP. Logarithmic deformation: 4 (a), 6 (b) and 8 (c)

Fig. 2. Diffraction pattern and structure of steel AISI 316 after ECAP. (Log. deformation: 8)

Mechanical properties

Samples after ECAP with number of passes (4, 5, 6) were used for investigation of influence of the ECAP technology on fatigue properties of the steel AISI 316 with special focus on the area of low-cycle fatigue.

Mechanical properties change in dependence on numbers of passes, strength properties (Rp0.2 and Rm) distinctly increase, plastic properties described, by narrowing almost do not change. Intensity of increase in Rp0.2 and Rm is shown in the Fig. 3. Micro-structural condition for increase of strength properties in investigated steel is fine grain and its stability. Several methods for grain refining and limitation of its growth are known at present – phase transformations, re-crystallisation, big plastic deformations (deformation of alloys with duplex structure, distribution of phases in duplex alloys, dispersion segregated particles), etc.

Selection of methods of grain refining and slowing of its growth is in individual cases given by state and properties of structure [6].

Increasing of mechanical properties in dependence on grain size is determined by the Hall-Petch relation:

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ykyd   (1) where

= the particle friction stress, and it is the yield stress for the limit d  ∞,

ky = the slope of the line and it is known as the dislocation locking parameter, which represents the relative hardening contribution due to grain boundaries.

For ordinary grade the following values are usually given  70 – 104 MPa and ky = 18.1 MPa mm1/2.

Fig. 3. Influence of number of passes on strength properties of steel AISI 316

Fatigue properties

Specimens for determination of the Manson – Coffin curve and cyclic stress-strain curve were prepared from extruded samples after 2 to 6 ECAP passes. Apart from extruded samples the initial state was tested as well.

The aim was to determine influence of number of ECAP passes on shape and position of both above mentioned curves.

Test of low-cycle fatigue were performed according to the standard ASTM E 606 at laboratory temperature on servo-hydraulic testing equipment MTS 100 kN at constant strain amplitude control.. Tests of low-cycle fatigue were carried out at constant rate 4.10-3 s–1.

During loading of individual testing specimens hysteresis curves were recorded, from which after failure of individual testing specimens the level of elastic (ael) and plastic deformation (apl) for Nf /2 was evaluated.

After end of each test the number of cycles till rupture Nf was recorded and from hysteresis curve for approximately N = Nf/2 for the chosen amplitude of total deformation ac there were read amplitude of plastic deformation apl, amplitude of elastic deformation ael and amplitude of stress a. Curves of service life expressed in the form were plotted from experimental data.

AISI 316

200 300 400 500 600 700 800 900 1000 1100 1200

0 1 2 3 4 5 6 7

Passes [1]

Rp0,2, Rm [MPa]

Rp0,2 Rm

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f c b f

f f pl ael

ac N N

E ( ) ( )

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200 300 400 500 600 700 800 900 1000

0 0,002 0,004 0,006 0,008 0,01 0,012 0,014

epsilonapl [1]

sigmaa [MPa]

as received 4 passes 5 passes 6 passes

Fig. 4. Dependence between the amplitude of stress and strain a - apl – cyclic stress-strain curves

Cyclic stress-strain curves were also determined for complex assessment of response of steel after the ECAP to alternating plastic deformation in push – pull:

apln

a k

. (3)

Manson-Coffin curves of service life were plotted from the obtained values, as well cyclic curve strain-stress curve. These values characterise deformation behaviour of material for prevailing time of its fatigue service life and they are therefore material characteristics. Results of individual test of low-cycle fatigue were processed in a form of graphic diagrams – as there is no places for presentation of all example is given in Fig.4 – effect of number of passes on cyclic deformation curves.

4. CONCUSIONS

Mechanical properties of the steel AISI 316 were determined by miniaturised tensile test. Basic mechanical properties of the steel AISI 316 were determined in dependence on number of passes. It was found that ECAP technology has a positive influence on mechanical properties. Yield stress can be elevated about four times with similarly same elongation compare to virgin state.

Structure analysis using SEM microscope shows that density of dislocations in metallic matrix was very high, presence of particles of precipitate was not found. In cases when neighbouring grains showed approximately identical diffraction contrast, it can be expected that angle of disorientation is only several degrees, while in case of significant changes of contrast rather high angular disorientation is probable. It was documented presence diffraction pattern, which was obtained from the area with diameter of approx. 1 m. Occurrence of

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discontinuous circles and at the same time azimuthal blurring of diffraction traces evidences the fact that big amount of fine sub-grains/grains with more or less different crystallographic orientation was present in the investigated area.

Fatigue behaviour of the steel AISI 316 was investigated after application of various numbers of passes through, structural stability was preserved, however, fatigue service life in the area of timed fatigue strength decreased after application of ECAP.

It follows from these results that materials with ultra-fine grain after intensive plastic deformation by the ECAP technology show at fatigue loading in the mode of constant amplitude of deformation (low-cycle fatigue) shorter fatigue service life in comparison with initial state. Nevertheless, it is possible to regard as highly positive the fact, that ultra-fine grained structure shows comparatively good mechanical stability after fatigue test, which is given by the fact that grains in structure are so small, that they prevent forming of dislocation structure. This fact conforms to the findings published in the work, where it was observed and verified on Cu.

ACKNOWLEDGMENTS

This paper was created in the project No. CZ.1.05/2.1.00/01.0040 " Regional Materials Science and Technology Centre" within the frame of the operation programme " Research and Development for Innovations" financed by the Structural Funds and from the state budget of the Czech Republic.

LITERATURE

[1] M. Greger, R. Kocich, L.Čížek, Z. Muskalski, Mechanical properties and microstructure of Al alloys produced by SPD process. Proceedings of the 10th International Conference “TMT ´06”, Barcelona, 2006, 253-256.

[2] A. Nowotmik, J. Sieniawski, M. Wierzbinska, Austenite decomposition in carbon steel under dynamic deformation conditions, Journal of Achievements in Materials and Manufacturing Engineering 20 (2006) 267-270.

[3] M. Jablonska, K. Rodak, G. Niewielski, Characterization of the structure of FeAl alloy after hot deformation, Journal of Achievements in Materials and Manufacturing Engineering 18 (2006) 107-110.

[4] M. Borisova, S.P. Yakovleva, A.M. Ivanov, Equal channel angular pressing its effect on structure and properties of the constructional steel St3, Solid state Phenomena 114 (2006) 97-100.

[5] K. Rodak, M. Pawlicki, Microstructure of ultrafine-grained Al produced by severe plastic deformation, Archives of Material Science and Engineering 28 (2007) 409-412.

[6] L.A. Dobrzański, Fundamentals of Materials Science and Physical Metalurgy. Engineering Materiále with Fundamentals of Materiále Design, WNT, Warzawa, 2002 (in Polish)

References

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