钒在钢渣中及钢中行为的热力学分析
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摘要
长期以来,由于氮与各种脆性现象的不良效果有关,所以一直被炼钢工作者视为不利因素。但是近年来由氮与合金元素相互作用产生的一些有效效果受到极大重视,从而开发出许多高氮的钢种。本文结合我国微合金化资源的特点,根据近年来国内外在钒氮微合金化技术方面的研究成果,介绍了钒氮微合金化技术的研究及其在实际生产中的应用。
高强度微合金钢中,氮与钒间的交互作用对提高钢材性能具有重要意义,为了准确控制钢中氮和钒的含量,多以氮化钒或氮化钒铁来实现合金化。本文用热力学方法,分析和讨论了以碳质和氢为还原剂还原钒氧化物制备金属钒和碳化钒,及其氮化过程的热力条件;对三元系几何模型进行了评价,利用统一溶液模型推导出三元系中组元活度相互作用系数预测的公式,并建立了CaO-FeO-SiO_2-V_2O_3四元渣系的活度模型。通过钒在钢中的热力学行为的分析,确定了钒微合金钢中碳氮化钒固溶量及化学组成。得出了影响钒收得率的因素主要是冶炼钢种成分、炉渣成分和渣量。并在钒微合金钢生产热轧三级钢筋中得到验证。为以后的生产提供有效的理论依据。
For the relevancy of N to unfavored brittleness effects, it has being seen as ill factors by metallurgical circle for a long period, while this is changed by the development of high N steels on the basis of the understanding and focus on desired interacition of N with alloy-making elements. With a comprehensive overview on the status quo and the worldwide evolution of VN microalloying as introduction, this thesis deals with the study and application of VN microalloying.
Interactive effects of Vanadium and Nitrogen plays an important role in improve performances of high strength low alloy steels (HSLAS). The forms of VN, VCN, FeVN are introduced into HSLAS for accurate content control of V and N. Taking dynamics as main tools, the article is dedicated to the analyze and discussion of the preparation of V and VC from vanadium oxide with carbon and hydrogen as reduction reagents, and the themodynamics conditions for the nitrification of the sequent productions (V and VC). New formulae for the calculations of AIC of components in ternary system the paper are established by uniform solution modeling on the basis of evaluations of geometric modeling for ternary system, which leads to the conclusion of the prominent feasibility of uniform solution modeling for analyze thermodynamic performance of ternary system. To expand the study, activity modeling for quaternary system of CaO-FeO-SiO_2-V_2O_3 of steel slag is deduced and main V recovery influencing factors is found in components of steel and slag, the slag ratio. The VCN content of solid solution form and chemical formula in vanadium microalloy steel is determined, and is verified in the production of the 3~(rd) class steel made of vanadium microalloy steel. The work will eventually facilitate practical production.
高强度微合金钢中,氮与钒间的交互作用对提高钢材性能具有重要意义,为了准确控制钢中氮和钒的含量,多以氮化钒或氮化钒铁来实现合金化。本文用热力学方法,分析和讨论了以碳质和氢为还原剂还原钒氧化物制备金属钒和碳化钒,及其氮化过程的热力条件;对三元系几何模型进行了评价,利用统一溶液模型推导出三元系中组元活度相互作用系数预测的公式,并建立了CaO-FeO-SiO_2-V_2O_3四元渣系的活度模型。通过钒在钢中的热力学行为的分析,确定了钒微合金钢中碳氮化钒固溶量及化学组成。得出了影响钒收得率的因素主要是冶炼钢种成分、炉渣成分和渣量。并在钒微合金钢生产热轧三级钢筋中得到验证。为以后的生产提供有效的理论依据。
For the relevancy of N to unfavored brittleness effects, it has being seen as ill factors by metallurgical circle for a long period, while this is changed by the development of high N steels on the basis of the understanding and focus on desired interacition of N with alloy-making elements. With a comprehensive overview on the status quo and the worldwide evolution of VN microalloying as introduction, this thesis deals with the study and application of VN microalloying.
Interactive effects of Vanadium and Nitrogen plays an important role in improve performances of high strength low alloy steels (HSLAS). The forms of VN, VCN, FeVN are introduced into HSLAS for accurate content control of V and N. Taking dynamics as main tools, the article is dedicated to the analyze and discussion of the preparation of V and VC from vanadium oxide with carbon and hydrogen as reduction reagents, and the themodynamics conditions for the nitrification of the sequent productions (V and VC). New formulae for the calculations of AIC of components in ternary system the paper are established by uniform solution modeling on the basis of evaluations of geometric modeling for ternary system, which leads to the conclusion of the prominent feasibility of uniform solution modeling for analyze thermodynamic performance of ternary system. To expand the study, activity modeling for quaternary system of CaO-FeO-SiO_2-V_2O_3 of steel slag is deduced and main V recovery influencing factors is found in components of steel and slag, the slag ratio. The VCN content of solid solution form and chemical formula in vanadium microalloy steel is determined, and is verified in the production of the 3~(rd) class steel made of vanadium microalloy steel. The work will eventually facilitate practical production.
引文
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[44] 梁连科等著.冶金热力学及动力学.沈阳:东北工学院出版社,1990.
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[46] 田燕,等.微钛合金化对15MnVN钢焊后时效韧性的改善[A].北京:科学技术出版社,1992,342.
[47] 刘嘉禾.钒、铌、钛等微合金元素在低合金钢中应用基础的研究[C].北京:科学技术出版社,1992,348.
[48] 陈茂爱,唐逸民,楼松年,等.Ti-V-Nb微合金管线钢中的第二相粒子分析[J].钢铁钒钛,2000,19(3):34.
[49] ADRAIN H, PICKERING F B. Effect of Ti addition on austenite grain growth kinetics of medium carbon V-Nb steels containing 0.008-0.18% N[J] Material Science and Technology 1991, 7(2): 176-182.
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[55] R 兰纳伯格,杨才福,等译.钒在微合金化钢中的作用[J].钢研总院内部资料.
[2] 马智明.译.微合金钢在性能和经济方面的协调[J].河南冶金,2001,(5):19-22.
[3] 陈博时.钒和氮微合金化的高强低碳锰钢[J].上海钢研,1999,(2):58-60.
[4] 杨才福.钒、氮微合金化钢筋的强化机制[J].钢铁,2001,(5):55-57,78.
[5] 夏茂森.VN12合金在钒氮微合金化钢中的应用研究[J].钢铁钒钛,2000,(3):23-28.
[6] 苏世怀,完卫国,等.VN微合金化HRB400(VN)热轧带肋钢筋试制[J].钢铁钛,2003,(3):46-51.
[7] 杨才福.氮在非调质钢中的作用[J].钢铁钒钛,2000,(3):16-22.
[8] 卢向阳.VN合金在非调质钢中的应用[J].钢铁钒钛,2000,(3):29-33.
[9] 唐新民.非调质钢弯、直臂的开发应用[J].金属热处理,2001,(1):43-45.
[10] 黄盛连.15MnVN钢的焊接性及焊接缺陷[J].水利电力施工机械,1997,(2):37,44.
[11] 李四年.氮对铬白口铸铁组织和性能的影响[J].湖北工学院学报,1997,(3):15-19.
[12] 沈国雄.氮对奥氏体不锈钢组织和力学性能的影响[J].钢铁研究学报,1997,(6):33-36.
[13] 曹荫之.中国含钒低、微合金化钢的开发与前景[J].钢铁钒钛,2000,(3):2-11.
[14] 翁宇庆.超细晶钢—钢的组织细化理论与控制技术[M].北京:冶金工业出版社,2003.
[15] 李午申.我国合金钢结构的新发展及其焊接性[J].焊接学报,2001,122(10):2-3.
[16] 赵西城.机械工程材料学[M].西安:陕西科学出版社,1998.
[17] Cheng Xu, Furukawa M, Horita Z et al. Severe plastic deformation as a processing tool for developing superplastic metals [J]. Journal of Alloys and Compounds, 2004, 378:27~30.
[18] 王立忠.西安建筑科技大学硕士论文[D].1998.4.
[19] 完卫国,等钒氮微合金化技术的研究与应用综述[J].江西冶金,2004,(5):27-29.
[20] 周勇.钒氧化物矿直接合金化冶炼含钒合金刚工艺的研究[J].2006,(3):56-57.
[21] 黄道鑫.提钒炼钢[M].北京:冶金工业出版社,2000.
[22] 徐先锋.五氧化二钒制备氮化钒的过程研究[J].钢铁钒钛,2000,(3):46.
[23] Yang Caifu, Zhang Yongquan, Liu shuping. Precipitation Behavior of Vanadium in V-N Micro alloyed rebar Steels. HSLA Steels 2000, Xi'an China.2000. 152-157.
[24] 钒渣的氧化[M].北京:冶金工业出版社1983.
[25] 刘天中.钒渣的熔融还原研究[D].中科院化工冶金研究所,1990.
[26] 刘天中,王大光,宣德茂.碳饱和铁水与CaO-SiO_2-VxOy熔渣平衡体系间各组元的分配[J].钢铁钒钛,1991,12(4):1-4,12.
[27] 涂世伟,王大光,宣德茂.钒钛渣系与碳饱和铁水间的熔融还原研究[J].钢铁钒钛,1989,(2):44.
[28] 曲彦平,杜鹤桂.含MnO钛渣中氧化钒还原能力的研究[J].钢铁钒钛,1997,(1):9.
[29] 黄务涤,殷雁.钒渣直接合金化的反应动力学[A].第六届冶金过程物理化学学术会议论文集[C],2003.
[30] 梁永安.攀钢钒钛渣钛钒直接合金化工艺研究[J].炼钢1982,(4):31.
[31] Korchynsky M.A New Role for Microalloyed Steels: Adding Economic Value. Infacon 9, Qebec City, Canads, 2001, 6.
[32] Narita K. Physical Chemistry of the Groups Ⅳ, (Ti, Zr), Ⅴ,(V, Nb,Ta) and the Rare Earth Elements in Steel[J].Trans ISIJ, 1975,1:145~152.
[33] P.K.Tripathy, A.Arya and D.K.Bose. Preparation of vanadium nitride and its subsequent metallization by thermal decomposition Journal of Alloys and Compounds. 1994, vol. 209:175-180.
[34] 徐有邻.混凝土结构用钢筋发展的探讨[A]Ⅲ级钢筋推广暨钒氮合金化技术研讨会论[C]1北京:中金属公司,20001911.
[35] 张永权,等.钒氮微合金化钢筋的研究[J]钢铁钒钛,2000,21(3):12)151.
[36] zajacS,等.氮在微合金钢中的作用[A]新Ⅲ级钢筋推广暨钒氮合金化技术研讨会论文[C]1 北京:中信金属公司,2000,12-14.
[37] 陈厚生.碳化钒与氮化钒.钢铁钒钛,2000.(21):70.
[38] 有色金属提取冶金手册.编辑委员会.稀有高熔点金属.北京:冶金工业出版社,2000.
[39] 田乃媛.薄板坯连铸连轧[M].北京:冶金工业出版社,1998.7.
[40] 雍岐龙,吴宝榕,白埃民,等.铌微合金钢中碳氮化铌化学组成的计算与分析[J].钢铁研究学报,1990,2(2):37-42.
[41] 梁连科.氮化铁合金的研制及其有关问题.铁合金,1998,29(4):15~17,41.
[42] 魏寿昆编著.冶金过程热力学.上海:科学技术出版社,1980.
[43] 加西克M,H拉基舍夫和叶姆林著.铁合金生产的理论和工艺.北京:冶金工业版社,1994,378.
[44] 梁连科等著.冶金热力学及动力学.沈阳:东北工学院出版社,1990.
[45] 车阴昌编著.冶金热力学.沈阳:东北工学院出版社,1987.
[46] 田燕,等.微钛合金化对15MnVN钢焊后时效韧性的改善[A].北京:科学技术出版社,1992,342.
[47] 刘嘉禾.钒、铌、钛等微合金元素在低合金钢中应用基础的研究[C].北京:科学技术出版社,1992,348.
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