Study on Behavior of Inclusions Removal from GCr15  Bearing Steel by Refining Slag

Abstract

Abstract: By established a model of inclusions dynamic at the steel-slag interface the refining slag absorbing inclusions phenomenon is studied. Results show that certain parameters, i. e. particle size, interfacial tension and slag viscosity ,determine the inclusions transfer behavior. Paiticle size and interfacial tension determine definitely large size inclusions transfer behavior, while interfacial tension only determines definitely micro size inclusions rating ≤20 ㎛ transfer behavior. Macro-sizes affects the inclusions displacement more than the Micro-sizes. For the removal of Micro-inclusions, by inclusions mathematical dynamic model coupled by steel and slag surface tension models, the effect of interfacial tension on obsorbing process has been studied. It is obvious that the particles blow 122.9 ㎛ size could be rebounded into steel when they are flowed to steel-slag interface layer. It is obtained that there is no way by re-designing refining slags to effectively remove ≤ 122. 9 ㎛ micro-inclusions from steel to slag layer and further to get the aim to decrease the oxygen content in steel.

摘要： 通过建立的夹杂物穿越钢渣界面运动模型，研究了精炼渣对夹杂物的吸附现象。结果表明，夹杂物粒径、表面张力和熔渣粘度是影响夹杂物冲破钢渣界面的重要参数，大型夹杂物中粒径和熔渣粘度起决定作用，而 ≤ 20㎛级别的小型夹杂物中仅表面张力起决定作用;大型夹杂物冲破钢渣界面的能力远大于小型夹杂物。针对小型夹杂物难以吸附的问题，运用了夹杂物运动模型和熔渣、钢液表面张力模型，研究了表面张力对吸附过程的影响。结果表明，直径≤ 122.9 ㎛尺寸的夹杂物均无法穿越钢渣界面，回弹至钢液一侧，由此得出：无法通过调整精炼渣用以吸附≤ 122.9 ㎛夹杂物以达到进一步降低钢中氧含量的目的。

Zhao Xinkai, Shi Yongsheng, Liu Shiyi, Wang Delong, Zhang Jiongming. Study on Behavior of Inclusions Removal from GCr15 Bearing Steel by Refining Slag[J]. Special Steel, 2022, 43(3): 14-20.

赵新凯, 石永生, 刘世义, 王德龙, 张炯明. GCrl5轴承钢精炼渣对夹杂物祛除行为的研究[J]. 特殊钢, 2022, 43(3): 14-20.

References

[1]Eid N and Thomason P F. The Nucleation of Fatigue Cracks in a Low-Alloy Steel Under High-Cycle Fatigue Conditions and Uniaxial Loading[J]. Acta Metallurgical, 1979, 27(7)： 1239-1249.
[2]Itoh H, Hino M and Ban-Ya S. Thermodynamics on the Formation of Spinel Nonmetallic Inclusion in Liquid Steel [J]. Metallurgical and Materials Transactions B, 1997, 28(5) : 953-956.
[3] Yang W, Zhang I. and Wang X, et al. Characteristics of Inclusions in Low Carbon Al-Killed Steel during Ladle Furnace Refining and Calcium Treatment] J]. The Iron and Steel Institute of Japan International, 2013, 53(8)： 1401-1410.
[4]Yang S, Wang Q and Zhang L, et al. Formation and Modification of MgO.Al₂O₃-Based Inclusions in Alloy Steels [J].Metallurgical and Materials Transactions B, 2012, 43(4) : 731-750.
[5]Zhang L and Thomas B G. Inclusions in Continuous Casting of Steel [A]. XXIV National Steelmaking Symposium, Morelia, Mich, Mexico [C]. Citeseer, 2003： 2842.
[6]Yang Guangwei, Wang Xinhua and Huang Fuxiang, et al. Influence of Reoxidation in Tundish on Inclusion for Ca-Treated Al-Killed Steel [J]. Steel Research International, 2013, 85(5) ： 784-792.
[7]Cheng-Bin S, Wen-Tao Y and Hao W, et al. Simultaneous Modification of Alumina and MgO . Al₂O₃ Inclusions by Calcium Treatment During Electroslag Remelting of Stainless Tool Steel [J]. Metallurgical and Materials Transactions B, 2016, 48(1)： 1-1.
[8] Jiang M, Wang X and Chen B, et al. Fonnation of MgO . Al₂O₃ Inclusions in High Strength Alloyed Structural Steel Refined by CaO- SiO₂ -Al₂O₂ -MgO Slag [J]. The Iron and Steel Institute of Japan International, 2008, 48(7) : 885-890.
[9]Woo J, Szekely J and Castillejos A, et al. A study on the Mathematical Modeling of Turbulent Recirculating Flows in Gas-Stirred Ladles [J]. Metallurgical Transactions B, 1990, 21(2) : 269-277.
[10] Bouris D and Bergeles G. Investigation of Inclusion Re-Entrainment from the Steel-Slag Interface [J]. Metallurgical and Materials Transactions B, 1998 , 29(3) : 641-649.
[11] Wang L T, Zhang Q Y and Peng S H. Mathematical Model for Growth and Removal of Inclusion in a Multi-Tuyere Ladle during Gas-Stirring [J]. The Iron and Steel Institute of Japan International, 2005, 45(3): p.331-337.
[12]Abraham F F. Functional Dependence of Drag Coefficient of a Sphere on Reynolds Number [J]. The Physics of Fluids, 1970, 13 (8)： 2194-2195.
[13]Hirokazu T, Yoshiei K and Kenichi S, et al. Agglomeration and Flotation of Alumina Clusters in Molten Steel [J]. The Iron and Steel Institute of Japan International, 1999 , 39(5) : 426-434.
[14]Morrison F A. Data Correlation for Drag Coefficient for Sphere[J]. Department of Chemical Engineering, Michigan Technological University ,Houghton, MI, 2013,49931.
[15]Clift R, Grace J R and Weber M E. Bubbles, Drops, and Particles [J]. American Scientist, 1978 , 67(4) , 491-492.
[16]Strandh J, Nakajima K and Eriksson R. Solid Inclusion Transfer at a Steel-Slag Interface with Focus on Tundish Conditions] J]. The Iron and Steel Institute of Japan International, 2005, 45 ( 11 )： 1597-1606.
[17]Strandh J, Nakajima K and Eriksson R, et al. A Mathematical Model to Study Liquid Inclusion Behavior at the Steel-Slag Interface [J]. The Iron and Steel Institute of Japan International, 2005,45 (12)： 1838-1847.
[18]Yang S, Li J and Liu C, et al. Motion Behavior of Nonmetal Inclusions al the Interface of Steel and Slag. Part II: Model Application and Discussion [J]. Metallurgical and Materials Transactions B, 2014 , 45(6)； 2453-2463.
[19]Liu C, Yang S and Li J, et al. Motion Behavior of Nonmetallic Inclusions at the Interface of Steel and Slag. Part 1: Model Development ,Validation, and Preliminary Analysis[J]. Metallurgical and Materials Transactions B, 2016, 47(3) : 1882-1892.
[20]Zhang J. Coexistence Theory of Slag Structure and Its Application to Calculation of Oxidizing Capability of Slag Melts [J]. Journal of Iron and Steel Research (International) , 2003, 10( 1) : 1 -10.
[21 ] Rein R and Chipman J. Activites in Ijquid Solution SiO₂-CaO- MgO-Al₂O₃ at 1600 Degrees [J]. JOM-JOLIRNAL OF METALS, 1964, 16(9)： 777-782.
[22]Wang P, Ma T and Zhang J. The Model of Mass Action Concentration for Slag System of CaO-SiO- Al₂O₃ -MgO and its Application [J]. Iron and Steel-Beijing-, 1996, 31 : 27-31.
[23]Butler J. The Thermodynamics of the Surfaces of Solutions [J]. P Proceedings of the Royal Society of London. Series A, 1932, 135 (827)： 348-375.
[24]Nakamoto M, Kiyose A and Tanaka T,et al. Evaluation of the Surface Tension of Ternary Silicate Melts Containing A12O3 , CaO, FeO, MgO or MnO [J]. The Iron and Steel Institute of Japan International, 2007,47(1) ：3843.
[25]Mukai K, Matsushita T and Mills K C, et al. Surface Tension of Liquid A Hoys-A Thermodynamic Approach [J]. Metallurgical and Materials Transactions B, 2008, 39(4) : 561-569.
[26]Kawai Y, Mori K and Kishimoto M, et al. Surface Tension of Liquid Fe-C-Si Alloy8[J].Tetsu-to-Hagane, 1974, 60(1)： 29-37.
[27]王景唐，边茂恕，马禄铭.液态Fe-Mn和Fe-S二元系表面组成的研究[J].金属学报,1986, 22(3):95-99.
[28]Sharan A, Nagasaka T and Cramb A W. Surface Tensions of Liquid Fe-Cr and Fe-Cr-N Alloys J . Metallurgical and Materials Transactions B, 1994 , 25(4) : 626-628.
[29]王新华，姜敏，于会香，等.超低氧特殊钢中非金属夹杂物研究[J].炼钢，2015, 31(6)： 1-12.
[30]Nakaoka T, Taniguchi S and Matsumoto K, e! al. Particle-Size- Grouping Method of Inclusion Agglomeration and its Application to Water Model Experiments [J]. The Iron and Steel Institute of Japan International, 2001,41 (10): 1103-1111.
[31 ] Uesugi T. Recent Development of Bearing Steel in Japan [J]. Tet- su-to-Hagane, 1988, 74(10) : 1889-1894.
[32]Van B J, Tiekink K and Visser H. Clean Steel 7 [J]. Ironmaking Steelmaking, 2008, 35(2) : 81-90.
[33]Almcrantz M, Andersson M A and Jonsson P G. Determination of Inclusion Characteristics in the Asea - SKF Process using the Modified Spark - Induced OES Technique as a Complement in Studying the Influence of Top Slag Composition [J] . Steel Research International, 2005 , 76(9)： 624-634.
[34]Yoon B H, Heo K H and Kim J S, et al. Improvement of Steel Cleanliness by Controlling Slag Composition[J]. Ironmaking Steelmaking, 2002,29(3) ：214-217.
[35]Riyahimalayeri K, Olund P and Selleby M. Oxygen Activity Calculations of Molten Steel: Comparison with Measured Results [J]. Steel Research International, 2013,84(2) ： 136-145.
[36]Fandrich R, Lüngen H B and Wuppermann C D. Actual Review on Secondary Metallurgy [J]. Revue de Metallurgie, 2008, 105 ( 7- 8): 364-374.

Study on Behavior of Inclusions Removal from GCr15 Bearing Steel by Refining Slag

GCrl5轴承钢精炼渣对夹杂物祛除行为的研究

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics

Comments