The combined influence of grain size distribution and dislocation density on hardness of interstitial free steel

doi:10.1016/j.jmst.2019.11.025

Abstract

Abstract:

Understanding the relationship between microstructure features and mechanical properties is of great significance for the improvement and specific adjustment of steel properties. The relationship between mean grain size and yield strength is established by the well-known Hall-Petch equation. But due to the complexity of the grain configuration within materials, considering only the mean value is unlikely to give a complete representation of the mechanical behavior. The classical Taylor equation is often used to account for the effect of dislocation density, but not thoroughly tested in combination with grain size influence. In the present study, systematic heat treatment routes and cold rolling followed by annealing are designed for interstitial free (IF) steel to achieve ferritic microstructures that not only vary in mean grain size, but also in grain size distribution and in dislocation density, a combination that is rarely studied in the literature. Optical microscopy is applied to determine the grain size distribution. The dislocation density is determined through XRD measurements. The hardness is analyzed on its relation with the mean grain size, as well as with the grain size distribution and the dislocation density. With the help of the variable selection tool LASSO, it is shown that dislocation density, mean grain size and kurtosis of grain size distribution are the three features which most strongly affect hardness of IF steel.

Key words: Interstitial free steel, Hardness, Grain size distribution, Dislocation density

Wei Li, Martina Vittorietti, Geurt Jongbloed, Jilt Sietsma. The combined influence of grain size distribution and dislocation density on hardness of interstitial free steel[J]. J. Mater. Sci. Technol., 2020, 45: 35-43.

Figures/Tables 10

References 35

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Heat treatment routes	Mean hardness (HV)	Hardness std. (HV)	Dislocation density (10¹⁰ m^-2)	Dislocation density error (10¹⁰ m^-2)
1000 °C 10 min 1 °C s^-1	58.6	1.5	1	-
1000 °C 10 min 750 °C 5 min Q	60.9	2.4	1	-
1000 °C 10 min 800 °C 5 min Q	62.0	1.3	1	-
1000 °C 10 min 850 °C 5 min Q	62.3	1.6	1	-
1000 °C 10 min 700 °C 5 min Q	64.9	0.9	1	-
1000 °C 10 min 80 °C s^-1	66.7	2.3	1	-
800 °C 5 min Q	68.1	0.5	1	-
1000 °C 10 min 200 °C s^-1	69.1	1.7	3.1	0.9
700 °C 5 min Q	75.9	3.2	1	-
400 °C 5 min Q	80.1	1.3	1	-
CR 3 mm	127.3	2.3	43	3
CR 1.7 mm	139.9	2.2	75	4
CR 1.13 mm 600 °C 75 min Q	141.8	1.6	12	2
CR 1.13 mm 450 °C 9 min Q	159.6	2.4	60	4
CR 1.13 mm 400 °C 9 min Q	163.4	2.0	75	5
CR 1.13 mm	167.0	1.9	72	4

Heat treatment routes	Mean hardness (HV)	Hardness std. (HV)	Dislocation density (10¹⁰ m^-2)	Dislocation density error (10¹⁰ m^-2)
1000 °C 10 min 1 °C s^-1	58.6	1.5	1	-
1000 °C 10 min 750 °C 5 min Q	60.9	2.4	1	-
1000 °C 10 min 800 °C 5 min Q	62.0	1.3	1	-
1000 °C 10 min 850 °C 5 min Q	62.3	1.6	1	-
1000 °C 10 min 700 °C 5 min Q	64.9	0.9	1	-
1000 °C 10 min 80 °C s^-1	66.7	2.3	1	-
800 °C 5 min Q	68.1	0.5	1	-
1000 °C 10 min 200 °C s^-1	69.1	1.7	3.1	0.9
700 °C 5 min Q	75.9	3.2	1	-
400 °C 5 min Q	80.1	1.3	1	-
CR 3 mm	127.3	2.3	43	3
CR 1.7 mm	139.9	2.2	75	4
CR 1.13 mm 600 °C 75 min Q	141.8	1.6	12	2
CR 1.13 mm 450 °C 9 min Q	159.6	2.4	60	4
CR 1.13 mm 400 °C 9 min Q	163.4	2.0	75	5
CR 1.13 mm	167.0	1.9	72	4

Heat treatment routes	μ_d (μm)	s (μm)	Skewness	Kurtosis
1000 °C 10 min 1 °C s^-1	159.1	94.0	0.68	-0.20
1000 °C 10 min 750 °C 5 min Q	135.8	95.5	1.02	0.51
1000 °C 10 min 800 °C 5 min Q	145.0	113.3	1.13	0.41
1000 °C 10 min 850 °C 5 min Q	92.5	59.0	0.88	0.20
1000 °C 10 min 700 °C 5 min Q	123.9	111.7	1.59	2.24
1000 °C 10 min 80 °C s^-1	71.6	53.7	0.99	0.32
800 °C 5 min Q	32.9	18.9	1.04	0.85
1000 °C 10 min 200 °C s^-1	122.5	70.0	0.75	0.20
700 °C 5 min Q	32.4	20.3	0.86	0.39
400 °C 5 min Q	31.0	18.8	0.81	0.45
CR 3 mm	28.3	16.0	0.63	0.22
CR 1.7 mm	24.2	20.1	1.25	1.42
CR 1.13 mm 600 °C 75 min Q	24.8	25.5	2.01	5.54
CR 1.13 mm	26.8	24.5	1.51	2.19

Heat treatment routes	μ_d (μm)	s (μm)	Skewness	Kurtosis
1000 °C 10 min 1 °C s^-1	159.1	94.0	0.68	-0.20
1000 °C 10 min 750 °C 5 min Q	135.8	95.5	1.02	0.51
1000 °C 10 min 800 °C 5 min Q	145.0	113.3	1.13	0.41
1000 °C 10 min 850 °C 5 min Q	92.5	59.0	0.88	0.20
1000 °C 10 min 700 °C 5 min Q	123.9	111.7	1.59	2.24
1000 °C 10 min 80 °C s^-1	71.6	53.7	0.99	0.32
800 °C 5 min Q	32.9	18.9	1.04	0.85
1000 °C 10 min 200 °C s^-1	122.5	70.0	0.75	0.20
700 °C 5 min Q	32.4	20.3	0.86	0.39
400 °C 5 min Q	31.0	18.8	0.81	0.45
CR 3 mm	28.3	16.0	0.63	0.22
CR 1.7 mm	24.2	20.1	1.25	1.42
CR 1.13 mm 600 °C 75 min Q	24.8	25.5	2.01	5.54
CR 1.13 mm	26.8	24.5	1.51	2.19

Heat treatment	N total	Mean	Standard Deviation	SE of mean	Skewness	Kurtosis	Minimum	Median	Maximum	Range (Maximum-Minimum)	P1	P99
1000 °C 10 min 1 °Cs^-1	84	159.1	94.0	10.3	0.68	-0.20	23.5	145.1	402.8	379.3	23.5	402.8
1000 °C 10 min 750 °C 5 min Q	105	135.8	95.5	9.3	1.02	0.51	17.9	113.9	419.6	401.6	18.0	395.6
1000 °C 10 min 800 °C 5 min Q	93	145.0	113.3	11.7	1.13	0.41	23.3	96.8	493.0	469.7	23.3	493.0
1000 °C 10 min 850 °C 5 min Q	63	92.5	59.0	7.4	0.88	0.20	14.3	87.3	242.6	228.4	14.3	242.6
1000 °C 10 min 700 °C 5 min Q	102	123.9	111.7	11.1	1.59	2.24	11.0	84.3	552.9	541.9	11.4	461.3
1000 °C 10 min 80 °Cs^-1	93	71.6	53.7	5.6	0.99	0.32	3.0	55.7	236.1	233.1	3.0	236.1
800 °C 5 min Q	214	32.9	18.9	1.3	1.04	0.85	4.5	28.4	100.6	96.1	6.5	85.0
1000 °C 10 min 200 °Cs^-1	107	122.5	70.0	6.8	0.75	0.20	18.2	108.3	353.2	335.0	20.6	318.1
700 °C 5 min Q	198	32.4	20.3	1.4	0.86	0.39	1.4	29.2	102.9	101.5	2.2	92.6
400 °C 5 min Q	214	31.0	18.8	1.3	0.81	0.45	1.5	28.3	96.3	94.7	3.1	80.2
CR 3mm	195	28.3	16.0	1.1	0.63	0.22	1.6	26.4	79.8	78.2	2.1	74.3
CR 1.7mm	273	24.2	20.1	1.2	1.25	1.42	1.3	19.4	94.5	93.2	1.5	92.2
CR 1.13 mm 600 °C 75 min Q	257	24.8	25.5	1.6	2.01	5.54	1.3	15.9	161.7	160.4	1.6	117.0
CR 1.13 mm	284	26.8	24.5	1.5	1.51	2.19	1.3	19.4	130.5	129.2	1.7	104.2