Research on Flange Spread of H-Beamon Universal Mill

The deformation process of H-beams was simulated by explicit dynamic FEM, and the influence of deformation parameters on the spread of rolling piece was obtained. The results show that the flange width, elongation ratio between flange and web and flange thickness are the maior influencing factors on the spread of rolling piece, and the inclination and diameter of vertical roll together with web inner width can also influence to some extent on the spread of rolling piece.

Microstructures and Properties of 550 MPa Grade High Strength Thin-walled H-beam Steel

The microstructures and mechanical properties of 550 MPa grade lightweight high strength thin-walled H-beam steel were experimentally studied. The experimental results show that the microstructure of the air-cooled H-beam steel sample is consisted of ferrite, pearlite and a small amount of granular bainites as well as fine and dispersive V（C,N） precipitates. The microstructure of the water-cooled steel sample is consisted of ferrite and bainite as well as a small amount of fine pearlites. The microstructure of the water-cooled sample is finer than that of the air-cooled sample with the average intercept size of the surface grains reaching to 3.5 gna. The finish rolling temperature of the thin-walled high strength H-beam steel is in the range of 750 ~C-850 ~C. The lower the finish rolling temperature and the faster the cooling rate, the finer the ferrite grains, the volume fraction of bainite is increased through water cooling process. Grain refinement strengthening and precipitation strengthening are used as major strengthening means to develop 550 MPa grade lightweight high strength thin- walled H-beam steel. Vanadium partially soluted in the matrix and contributes to the solution strengthening. The 550 MPa grade high-strength thin-walled H-beam steel could be developed by direct air cooling after hot rolling to fully meet the requirements of the target properties.

H-Beam Stripping Loss at Background Partial Pressure of Ar

It has been observed that H^- current could be improved by adding Ar to H2 plasma. But due to a slower pumping speed for Ar with the existing pumping scheme, the tank pressure will increase quickly during the length of a beam pulse. Since H^- stripping loss depends on the tank pressure and gas species, part of the H^- beam can be converted to H^0 and then H^0 can be converted into H^＋ with background H2 and Ar gas thickness. Therefore, the H^- beam current, measured by a Faraday cup, situated at a distance L from GG （ground grid）, will decrease because it will be converted into a H^＋ current. This gives a ratio of the Faraday cup net current to the H^- beam current before stripping at background partial pressure of Ar.

T型钢连接方钢管柱-H型钢梁节点抗震性能分析

目的为了研究单边螺栓和T型钢连接的方钢管柱-H型钢梁节点的抗震特性,方法采用室内试验和数值模拟分析方法,对1∶2缩尺的边节点进行拟静力试验,并通过ABAQUS有限元软件进行数值模拟,综合分析边节点的滞回特性、承载力、刚度与耗能等力学特性。有限元分析变量为T型钢加肋、梁翼缘狗骨式和梁腹板开圆孔式。结果试验中,节点试件中连接件T型钢参与耗能且其变形最明显,梁、柱构件变形较小。塑性铰主要集中在连接构件T型钢上,T型钢腹板与翼缘交接处出现应力集中状态。试验弹性阶段,节点构件共同抵抗外部作用力。进入塑性阶段,节点损伤逐渐累积至T型钢,使T型钢最终产生塑性破坏而失效。有限元模拟中,T型钢加肋的形式对节点整体承载力影响最大,其中加3号肋的形式使节点承载力的增长量达到最大;梁翼缘狗骨式的形式对节点整体耗能能力影响最大,为44.01%。结论在T型钢上加肋板对节点的承载力和刚度提升较明显,对耗能能力影响不大;梁翼缘狗骨式和梁腹板开圆孔式均能提高节点的耗能能力,节点承载力和刚度基本不变;梁翼缘做狗骨式对节点抗震性能影响最显著。

热轧H型钢不同冷却方式的温度场研究及优化

轧后对H型钢进行控制冷却,既能提高强度,又可以节约能源。为了改善热轧H型钢轧后冷却温度场,采用有限元数值模拟不同控冷工艺下的热轧H型钢温度场,并通过差别冷却方式获得相对均匀的温度场。结果表明,针对性地对H型钢圆角加强冷却后,H型钢断面整体温度分布比较均匀,6 s冷却后,腹板和圆角的温差小于45℃。

焊接空心球连接H型钢Z字形螺栓节点静力性能研究

提出了一种新型焊接空心球连接H型钢Z字形螺栓节点(新型螺栓节点),该节点适用于全装配大跨度弦支穹顶结构体系上部网壳连接。该节点的弦杆采用热轧H型钢,方便栓接、施工便捷、制造能耗低,可以实现部品部件到体系的标准化。为了研究新型螺栓节点的静力性能,对该节点进行了轴压、轴拉、纯弯和压弯荷载工况下的有限元分析,研究了该节点在不同荷载工况下的破坏模式、承载力、刚度、延性等力学性能指标,对比分析了新型螺栓节点与焊接空心球连接H型钢焊接节点(焊接节点)的破坏模式和静力性能。研究表明,在轴压和压弯荷载下新型螺栓节点和焊接节点的极限破坏模式均为H型钢弦杆局部屈曲和屈服,在轴拉荷载下新型螺栓节点和焊接节点的极限破坏模式均为H型钢弦杆全截面屈服,在纯弯荷载下新型螺栓节点和焊接节点的极限破坏模式均为H型钢弦杆局部屈曲。新型螺栓节点可以实现塑性铰远离焊缝和拼接区,符合“强连接,弱杆件”的设计要求。

工字形钢梁-矩形钢管柱单向螺栓节点抗弯承载力理论计算方法

针对工字形纯钢梁和钢-混凝土组合梁分别与矩形钢管柱和矩形钢管混凝土柱采用单向螺栓(也称单边拧紧螺栓)连接形成的4种节点形式,对其在弯矩作用下的受力机理及破坏模式进行分析,讨论导致节点失效的因素。总结节点在弯矩作用下的9种失效模式,包括:单向螺栓拉断、端板受弯屈服、矩形钢管柱壁翼板受拉屈服、矩形钢管柱壁翼板受压屈服、矩形钢管柱壁腹板受压屈曲、混凝土楼板局部压溃、钢筋屈服、矩形钢管柱内混凝土局部压溃、矩形钢管柱壁腹板受压屈服,进而基于破坏模式给出节点各组件承载力的计算公式。对4种节点在不同破坏模式下的正弯矩承载力和负弯矩承载力进行分析,给出节点承载力计算公式。将节点抗弯承载力的理论计算结果与试验结果进行对比,验证理论计算方法的可靠性。

HW300×300H型钢热力耦合模拟计算分析

以HW300×300为典型案例采用双线性硬化材料模型计算了H型钢变形过程中温度、应变、外形尺寸的变化,分析了轧制过程的变形特点。用全流程思维使用热力耦合计算方法进行计算,轧件变形温度使用过程温度,充分考虑了横断面温度不均匀的影响,计算结果更加接近真实情况,为工艺优化提供可靠依据。计算结果表明,由于不均变形导致H型钢腰部在三角区附近出现“颈缩”现象,翼缘端部的局部变形会导致翼缘宽度精度的变化,轧制变形功会转化为热能,导致轧件内部温度出现升高迹象。

热轧H型钢生产工艺技术

简述了H型钢的发展现状及H型钢的应用特点,从轧钢工艺方面介绍了小型、中型、大型H型钢国内比较常见的几种生产方法,包括全连续、半连续以及半连续往复穿梭轧制法,并通过国内主要型钢厂的实例,对几种轧制方法进行阐述。同时介绍了国内H型钢未来的发展趋势及新技术的应用。

不锈钢复合钢H形截面钢梁受剪承载性能

基于复合钢本构模型,明确了复合比β对不锈钢复合钢应力-应变性能的影响。通过试验结果的承载曲线和破坏模式验证了数值模拟方法的准确性,进而以β、腹板宽高比a/hw和腹板高厚比hw/tw为变量开展300个数值模型的参数分析,系统分析了各变量对不锈钢复合钢H形截面钢梁受剪承载曲线和极限承载力的影响。研究结果表明:随着β的增加,不锈钢复合钢应力-应变曲线中的屈服平台逐渐消失,复合钢应力-应变性能逐渐由碳钢转变为不锈钢。当β较小时,不锈钢复合钢应力-应变曲线存在明显的屈服平台,这削弱了复合钢的应变强化对H形截面钢梁受剪承载性能的有利影响。随着β的增加,不锈钢复合钢的非线性应变强化性能逐渐增强,导致H形截面钢梁的延性性能逐渐提高,强度性能逐渐降低。经过验证,既有的欧洲规范设计公式对不锈钢复合钢H形截面钢梁受剪极限承载力的预测过于保守。基于参数分析结果,建立了考虑β影响的腹板贡献系数计算方法。研究结论有助于推广不锈钢复合钢的工程应用。

碳纤维板加固H型钢梁抗剥离夹具研制及应用试验

外贴碳纤维板是钢梁抗弯加固的常用方法,但其端部易因界面应力集中导致剥离破坏,严重影响高性能材料的有效利用,特别是结构加固后的安全服役.为此开发出一种适用于H型钢梁的简易夹具——C形槽板夹,以加强碳纤维板的端部锚固.通过多根带夹碳纤维板加固梁的静力加载试验,验证了此夹具的可靠性,并考察了碳纤维板伸入剪跨段长度与剪跨段长度之比及锚固方式(纯粘、端锚和混锚)对加固效果的影响.研究发现端锚加固不同于纯粘,只要梁的控制截面仍在夹具之间,碳纤维板的极限应力、加固效果及利用效率均随其长度缩短而提高,当碳纤维板长度分别为600、750 mm时,前者极限应变和承载力比后者分别高27.3%和8.1%.由于钢梁表面处理质量较差,混锚加固梁均发生突然剥离,后期退化为端锚加固梁,因而相比端锚加固梁加固效果改善不大,需要提高表面处理质量再做类似研究.尽管如此,相比纯粘加固梁,混锚加固梁采用C形槽板夹后剥离破坏被延迟,抗弯性能大为改善.试验过程中还用压电阻抗法对界面剥离情况进行了检测,结果符合实际.

热轧H型钢万能轧机导卫系统研究

导卫装置的设计和使用是否恰当直接影响产品质量和轧机的生产能力。对长钢H型钢车间万能轧机导卫装配形式进行研究,在线探讨了UR-E-UF三台串联式轧机进出口腹板上下导卫装配要点。研究结果表明,该导卫装配形式可降低型钢车间非计划停机时间和工艺故障率,实现降本增效。

Effect of Cooling Rate and Deformation on Microstructures and Critical Phase-Transformation Temperature of Boron-Nickel Added HSLA H-Beams

Microstructures and critical phase-transformation temperature of boron-nickel added Nb-treated high strength low alloy （HSLA） H-beams cooled at different cooling rate, with different deformation were investigated. Continuous cooling transformation （CCT） diagram of this new type of steel was obtained by using Gleeble 1500 ther- momechanical simulator. Microstructures and hardness, especially micro-hardness of the experimental steel were in- vestigated by optical microscopy （OM）, scanning electron microscope （SEM）, Rockwell and Vickers hardness tests. Phase analysis was also studied by X^ray diffraction （XRD）. The results indicated that with increase of cooling rate, microstructures of continuous cooled specimens gradually transformed from polygonal ferrite and pearlite, grain boundary ferrite and bainite, bainite and martensite to single martensite. The CCT diagram revealed that slow cool- ing was needed to avoid austenite-bainite transformation to ensure toughness of this steel. By plastic deformation of 40%, austenite-ferrite transformation temperature increased by 46℃, due to deformation induced ferrite transfor- mation during continuous cooling, but Rockwell hardness has little change.

基于改进Yolov3的H型钢喷号识别系统研究

随着工业生产智能化程度不断提升,智能视频识别技术被逐渐广泛应用于工业生产中。针对马钢重型H型钢生产线精整区存在的工艺复杂、物料跟踪困难问题,提出一种在矫直机后用喷码机在钢坯上喷印批号、在堆垛区域人工检查台位置安装一套字符识别装置来识别批号并实现物料跟踪的方法。根据喷印字符相对较小且没有大小形态变化的特性,改进了Yolov3模型结构,设计5个不同尺度的卷积特征图,并与残差网络中相应尺度的特征图进行融合,形成最终的特征金字塔执行字符识别任务。试验结果表明,该方法的识别准确率能达到99.5%以上,可在工程上进行应用。

Effect of Controlled Cooling on Microstructure and Mechanical Properties of H-Beam

Based on ANSYS, an analytical model was established for H beam during controlled cooling. The tempera-ture fields during controlled cooling and air cooling were analyzed and the microstructure and mechanical properties for different parts of H-beam were discussed in detail. After the H-beam was controlled cooled for 4.5 s, its mean surface temperature decreased from 850 to 460 ℃, and the lowest and the highest temperatures were measured at edge of flange and at R corner, respectively. Whereas, for the H-beam air cooled for 30 s, the mean temperature at R corner and web was 700 and 540 ℃, respectively. The microstructures for different parts of H-beam consisted of ferrite and pearlite, and the grain size at R corner was coarser than those at flange and web. The difference of yield and tensile strengths of web, flange and R corner was within 30 MPa, and the elongation was similar. The changes of microstructure were in good agreement with that of temperature field. In addition, the results show that the uni formity of microstructure and mechanical properties can be improved by increasing water flow rate at R corner.

预应力碳纤维布加固钢梁抗弯性能的试验研究和有限元分析

为了研究预应力碳纤维增强聚合物(Carbon Fiber-Reinforced Polymer,CFRP)布加固钢梁抗弯性能,首先对未加固钢梁、CFRP布加固钢梁和预应力CFRP布加固钢梁进行单调加载试验。紧接着建立预应力纤维布加固钢梁的数值仿真模型,并通过试验验证了该模型。然后研究碳纤维布的长度和厚度、碳纤维布的预应力以及粘结剂的断裂强度和弹性模量对钢梁极限抗弯荷载的影响。最后,提出了预应力碳纤维布加固钢梁极限抗弯荷载的计算公式。研究结果表明,碳纤维布加固钢梁的典型失效模式有两种:碳纤维布的受拉断裂和碳纤维布与钢梁下翼缘间界面的粘结破坏。不同参数(碳纤维布的长度和厚度、碳纤维布的预应力以及粘结剂的断裂强度和弹性模量)对加固钢梁的极限抗弯荷载变化规律的影响是不同的,其中以碳纤维布的厚度和预应力最为明显。随着碳纤维布的预应力逐渐增大,加固钢梁的破坏模式由受弯破坏逐渐转变为受剪破坏。文章提出的预应力碳纤维布加固钢梁的极限抗弯荷载的计算公式预测值和数值仿真结果吻合较好。

控轧控冷工艺对Q235B热轧H型钢氧化铁皮特征及剥离性能的影响

对Q235B热轧坯料进行了实验室模拟轧制和弯折矫直试验。结合SEM、XRD等试验手段,研究了控轧控冷工艺参数对Q235B热轧H型钢氧化铁皮特征及其剥离性能的影响规律。结果表明:在其他轧制工艺参数相同的条件下,随着终轧温度的升高,氧化铁皮的厚度呈增加趋势,FeO相比率增加,Fe_(3)O_(4)相比率降低。随着冷却速度的提高,氧化皮的厚度呈减小趋势,FeO相比率增加,Fe_(3)O_(4)相比率降低。随着Fe_(3)O_(4)相比率增加,FeO相比率降低,氧化皮从大块剥离向小块剥离再向细粉状剥离过渡。

大跨径拼装H型钢叠合梁桥孔群制作精度控制技术

大跨径拼装H型钢叠合梁桥成为桥梁建设中的一种新型结构体系。通过拼装连接形成整体梁体,具有结构坚固、施工便捷、体积小、重量轻、拼装快、使用寿命长等优点,被广泛应用于各类公路、铁路、城市轨道交通等工程。然而,由于受产品制造精度和现场施工精度的限制,大跨径拼装H型钢叠合梁桥整体制作的精度往往无法满足设计要求。因此,为了提高该结构体系的制作精度,从桥孔群的制作精度控制方面入手,对其精度控制技术进行了研究和分析。

降低H型钢轧辊辊耗的技术研究

轧辊辊耗是H型钢成本控制的重要指标,轧辊和钢坯直接接触,辊耗消耗巨大,因而研究降低辊耗的方法对H型钢生产有重大意义。主要通过对H型钢开坯机轧辊、万能轧机水平辊环、万能轧机水平辊辊轴、轧边机轧辊、万能轧机立辊和矫直辊进行了一系列工艺技术改进,达到了降低辊耗的目的。

交叉指型磁模漂移管重离子直线加速器设计

西安200 MeV质子应用装置(XiPAF)的质子同步环改造为质子重离子同步环的需求,采用将电磁四极磁铁安装在漂移管内部的设计方案,完成了1台2 MeV/u的交叉指型磁模漂移管直线加速器(interdigital H-mode drift tube linear accelerator,IH-DTL)的物理设计和机械设计。建立了使用腔内聚焦散焦周期结构进行横向强聚焦,常规负相位用于纵向聚束的1套动力学设计方法,实现对多种离子的加速,并能在获得较高束流传输效率的同时保持较低的束流发射度增长。DTL动力学计算结果表明:该IH-DTL可将峰值电流强度为50 eμA的Bi^(32+)离子从0.4 MeV/u加速到2 MeV/u,传输效率为99%,横向归一化均方根发射度增长小于10%,可用于加速荷质比在1/2~1/6.5范围内的重离子。