共查询到19条相似文献,搜索用时 218 毫秒
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49MnVS3非调质钢(/%:0.47C,0.39Si,0.90Mn,0.016P,0.050S,0.22Cr,0.09V,0.015Ti,0.011Al,0.02Ni)的生产流程为铁水预处理-60t顶底复吹转炉-LF处理-VD真空脱气-220 mm×300 mm坯连铸-控轧控冷。研究了控轧控冷工艺对49MnVS3非调质钢组织和性能的影响。φ110 mm轧材试验工艺参数:加热温度1150~1250℃、开轧温度1 0500℃、终轧温度850℃、轧后冷却速度70℃/min、冷却开始温度850℃和终止温度500℃。结果表明,试验炉次粒度提高高.5~1.0级,带状组织减轻轻0.5~1.5级,硬度、强度及塑韧性均有所提升,获得良好的强韧性匹配。 相似文献
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采用中碳非调质钢制造的轴类等零件常承受交变载荷,因而对钢材疲劳性能具有高的要求。为了评估控轧控冷工艺生产的非调质钢棒材的疲劳性能,利用旋转弯曲疲劳试验机研究了一种常用的钒微合金化中碳非调质钢38MnVS及对比钢38MnS的高周疲劳性能。结果表明,与38MnS钢相比,38MnVS钢中铁素体体积分数增加,组织明显细化;相分析表明约有54%的钒处于M(C,N)相中,且尺寸小于10 nm的M(C,N)粒子质量分数为32%,这些细小粒子的析出强化增量约为116 MPa。38MnVS钢的疲劳极限较38MnS钢提高了62 MPa,提高幅度约为18%;疲劳极限比从38MnS钢的0.43提高到38MnVS钢的0.48。M(C,N)相的析出强化及组织细化是38MnVS钢较38MnS钢具有优异疲劳性能的主要原因,但其疲劳性能仍低于锻态非调质钢。根据试验结果及文献数据,给出了预测铁素体+珠光体型非调质钢疲劳极限的简便方法。 相似文献
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介绍了天津钢铁有限公司开发的N80级非调质石油套管钢的技术特点、工艺流程。实践证明,该工艺生产的产品化学成分、机械性能符合标准要求,用户满意。 相似文献
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非调质N80(F—N80)油井管用钢的开发 总被引:1,自引:0,他引:1
对42MnMo7油井管失效形式分析,提出了非调质(F-N80)成分设计方案,通过工业性试验,寻找出F-N80成分范围及轧制方案。 相似文献
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本文介绍了采用42MnMo7连铸方坯轧制N80油管用φ圆管坯的试生产工艺过程,检验分析了铸坯及轧坯的低倍质量、化学成分及显微组织等,研究结果表明包钢采用转炉连铸工艺生产的方坯表面及内部质量较好,可以轧制出质量符合用户要求的圆管坯。 相似文献
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对鞍钢采用氧气顶吹转炉(BOF)冶炼、非调质工艺开发的N80级油井管用钢进行了系统的工艺设计、实验室研究、工业实验及工业生产研究.提出了V、N微合金化取代常规淬火和回火工艺,设计了非调质N80的化学成分,确定了符合鞍钢氧气转炉大规模生产非调质N80的冶炼工艺以及各工序的工艺控制要点,特别是确定了实际工况下氧气转炉终点碳、氧、温度的回归公式以及VD底吹增氮动力学模型等关键工艺要点.连续生产的实测数据分析结果表明:非调质N80冶炼工艺稳定可行,化学成分、冶炼工艺设计合理,力学性能和使用性能均满足API Spec 5CT及油井管生产的特殊要求. 相似文献
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X80级高强低合金管线钢组织与冲击韧性 总被引:1,自引:0,他引:1
为了研究准多边形铁素体/板条贝氏体/粒状贝氏体显微组织的高强低合金X80管线钢的低温韧性与冲击裂纹扩展特点,用OM、SEM、EBSD和TEM等多尺度手段进行了表征。结果表明,与针状铁素体/粒状贝氏体相比,在-60 ℃以上时,准多边形铁素体/板条贝氏体/粒状贝氏体表现出更好的阻止裂纹扩展的能力,准多边形铁素体可以分割显微组织并细化有效晶粒尺寸,增加大角度晶界比例,协调约束冲击裂纹扩展,进而提高韧性;当温度在-60 ℃以下时,这种准多边形铁素体/板条贝氏体/粒状贝氏体对裂纹扩展的协调约束作用减弱,成为显微组织的“软区”,使得材料韧性下降。 相似文献
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L. Giuliani M. Mirabile M. Sarracino 《Metallurgical and Materials Transactions B》1974,5(9):2069-2073
The kinetics of hydrogen embrittlement of an N 80 steel have been studied in a Na2S-CH3COOH solution. Determination of hydrogen content, metal density and embrittlement degree, together with acoustic-emission
measurements have shown that the hydrogen distribution with-in the metal lattice is time-dependent and strongly influenced
by non-metallic inclusions. The inclusions cause local stress intensification, favoring hydrogen collection in the lattice
around them. Fracturing of charged specimens at different times evidences a mechanism of crack inactivation. An explanation
of crack inactivation in terms of plastic deformation around inclusions due to hydrogen-dislocation interaction is suggested. 相似文献
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A technology has been developed for producing a new grade of steel shots used in casting cleaning. The developed technology is based on obtaining molten steel with the specified chemical composition microalloyed with titanium and using a highly efficient method of dispersing molten steel stream by water jet under high pressure followed by spheroidisation of produced particles and their solidification in water bath. The chemical composition and tapping temperature have been adjusted and different parameters of atomization process such as molten stream nozzle internal diameter, impact angle, water nozzle system and water pressure have been optimized to attain steel shots with the desired mechanical properties, microstructure, density and grain size. After drying, the steel shots are screened to different sizes. The desired grain size is then subjected to only one‐step tempering process. This technique reduces the processing steps (by omission of the reheating‐quenching treatment) and consequently gives significant savings in processing cost. 相似文献
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Yurii Grigor'evich Gurevich 《Metallurgist》1996,40(10):197-198