Reaction characteristics of magnesium production under argon flow by silicothermic reduction and numerical simulation of argon entrainment process

In this study, the reaction characteristics of reduction of calcined dolomite with ferrosilicon under argon flow to produce magnesium were studied by conducting experiments Pidgeon pellets were used to study the effect of reduced temperature, argon flow, and reduced time on the conversion of calcined dolomite reduction by ferrosilicon. The results show that the conversion significantly increases with the increase in the reduction temperature and reduction time. The conversion first increases and then decreases with the increase in argon flow. The highest conversion was obtained when the argon flow rate was 3 L·min^(-1), and a nearly spherical shape, nanoscale magnesium powder was obtained. Then the characters of the circulating argon entrainment process were numerically studied by ANSYS Fluent 17. A physical model of multilayer pellet arrangement was established, and a numerical calculation model of chemical reaction, radiation, heat conduction, and convection heat transfer was constructed. This confirms that high-temperature argon can effectively strengthen the heat exchange between pellets, improve the heat transfer efficiency, and facilitate the pellets to react quickly. When the conversion is 80%, the production efficiency increased by about 28.6%. In addition, the magnesium production efficiency showed an increase tendency with the increase of the argon inlet flow rate.

Feasibility study of symmetric solution of molecular argon flow inside microscale nozzles

The computational cost of numerical methods in microscopic-scales such as molecular dynamics(MD) is a deterrent factor that limits simulations with a large number of particles. Hence, it is desirable to decrease the computational cost and run time of simulations, especially for problems with a symmetrical domain. However, in microscopic-scales, implementation of symmetric boundary conditions is not straightforward. Previously, the present authors have successfully used a symmetry boundary condition to solve molecular flows in constant-area channels. The results obtained with this approach agree well with the benchmark cases. Therefore, it has provided us with a sound ground to further explore feasibility of applying symmetric solutions of micro-fluid flows in other geometries such as variable-area ducts. Molecular flows are solved for the whole domain with and without the symmetric boundary condition. Good agreement has been reached between the results of the symmetric solution and the whole domain solution. To investigate robustness of the proposed method, simulations are conducted for different values of affecting parameters including an external force, a flow density, and a domain length. The results indicate that the symmetric solution is also applicable to variable-area ducts such as micro-nozzles.

吹氩模式对钢包内多相流流动行为影响的数值模拟研究

以某钢厂150 t钢包为对象,通过数值模拟手段研究了吹氩模式和吹氩流量对钢包流场、钢渣界面行为和壁面剪应力分布的影响。结果表明:单孔吹氩模式下,钢包内环流远端流速低,钢渣界面流动不活跃,易导致此处渣层冷凝结壳;双孔等流量吹氩模式下,随着吹氩流量增大,钢渣界面流速增加,但其流动活跃性降低;双孔差流量吹氩下,大吹氩流量时钢渣界面能维持一定范围的活跃流动。当吹氩流量在120~240 L/min范围,单孔吹氩所形成的渣眼面积大于两种双孔吹氩模式;当吹氩流量超过240 L/min,双孔等流量吹氩下渣眼面积最大,双孔差流量吹氩对应的渣眼面积最小。另外,单孔吹氩下壁面剪应力最大,应力面积较小,双孔等流量吹氩下剪应力虽然显著降低,但分布区域面积增大。综上所述,双孔差流量吹氩模式可以在提高钢液精炼效率的同时,降低对钢包内衬耐火材料的流动侵蚀。

氩气环境对激光诱导击穿光谱法检测钢中C、P、S元素的影响研究

激光诱导击穿光谱技术在实现钢水成分在线分析上展现了强大的应用潜力。然而,在测量钢中非常重要的C、P、S组成元素时,由于其有效的发射谱线无法在空气中远距离传输,这些元素的探测一直是个挑战。该论文工作研究了在1.5 m长探枪下,探枪中氩气环境对检测钢中C、P、S元素的影响规律,发现氩气流量过大或过小都不利于光谱测量,在气流量设置为11 L·min^(-1)时,获得的光谱最稳定且谱线强度最大。使用14个标准钢样本,在最优气流量下对C、P、S三种元素实现了明显检出以及定量分析。通过内标标定后,三种元素获得的检出限(LOD)分别为0.009%、0.04%、0.015%,相对标准偏差(RSD)分别为2.34%、1.05%、1.01%,相关系数(R)分别为0.998、0.997、0.987,均方根误差(RMSE)分别为0.02%、0.02%、0.03%。该论文研究成果验证了该探枪设计的有效性,为实现钢水成分中C、P、S在线分析提供了重要的设计依据。

底吹氩钢包内流动及界面传热行为的数值模拟研究

钢包底吹氩是二次精炼中的常用手段,在均匀温度和成分、促进钢渣界面反应、去除夹杂物等方面效果显著,然而底吹氩在搅拌钢液的同时会加剧壁面耐材熔损,降低钢液洁净度,影响钢包寿命和使用安全性。采用数值模拟的方法研究了底吹氩钢包内钢渣流动及固液间传热行为,分析了单孔和双孔吹氩下气泡上浮及钢渣界面行为,对比了钢包不同结构界面处温度分布,探讨了吹氩量对钢包内流动传热及界面温度分布的影响。结果表明:底吹氩钢包内气泡羽流呈倒锥状分布,随着距渣眼距离的增加,钢渣界面速度和温度逐渐降低;同一气量下,相较于单孔吹氩,双孔吹氩下气泡羽流扩张角增大,渣眼面积减小,钢渣界面最大速度和湍动能较小;钢包不同结构界面温度由内向外逐渐降低,各界面渣线高度位置和底部存在较大的温度梯度;底吹氩所形成的局部循环流会导致工作层壁面的近钢渣界面位置形成高温热点区域。增大吹氩量,壁面高温热点区域温度和范围增大,近钢渣界面壁面的最大周向温差在20 K左右,双孔吹氩模式和低吹氩量有利于减小壁面周向温差。

减少冷轧低碳钢轧材表面夹杂缺陷实践

针对冷轧低碳钢轧材表面夹杂缺陷问题,分析主要原因是结晶器保护渣卷入钢水导致,采取优化保护渣理化性能,优化铸机拉速、水口浸入深度和氩气流量等措施后,降低了卷渣风险,冷轧低碳钢表面夹杂缺陷指数由4降至1,提高了产品表面质量。

钢包氩气流量对冷镦钢SWRCH35K中DS夹杂物的影响

在精炼进站时采用BaCO_(3)作为示踪剂,对比钢包底吹氩气流量对“120 t BOF→LF→CCM”流程生产的冷镦钢SWRCH35K中DS类夹杂物的影响。结果表明,氩气流量对精炼结束炉渣成分及夹杂物的类型无明显影响;精炼进站到精炼结束采用小氩气和正常氩气搅拌夹杂物密度分别降低4.5个/mm^(2)和7.1个/mm^(2),精炼结束到中包两种工艺夹杂物变化相差不大,精炼正常氩气搅拌精炼结束、软吹后、中包含Ba的夹杂物比例比小氩气搅拌分别高51.5%、26.1%、39.3%。铸坯中DS夹杂物组成有单相、两相和三相。精炼采用小氩气搅拌和正常氩气搅拌铸坯中检测到含Ba的DS夹杂物占所有DS夹杂物的比例分别为28.6%和39%。所以,控制精炼过程中冶炼的氩气搅拌强度也是控制钢中DS夹杂物的关键。

拉晶工艺参数对N型单晶硅氧含量的影响研究

TOPCon电池基板是以N型硅片为主,N型硅片的氧含量在一定程度上影响着TOPCon电池的转换效率。本文采用直拉法进行单晶硅的拉制,通过调整埚转、氩气流量和炉压来研究拉晶工艺参数对N型单晶硅氧含量的影响。数值模拟分析和实验结果表明:坩埚转速的增加会抑制浮力-热毛细漩涡,减少熔体界面处SiO的挥发,提高硅熔体内部和单晶硅棒氧含量;增大氩气流量和降低炉压可增大熔体界面处SiO的质量流量,有效促进SiO挥发,减少固液界面处氧含量,从而降低单晶硅棒氧含量。根据单晶硅氧含量测试和EL检测结果可知,坩埚转速5 r/min、氩气流量100 L/min和炉压1 200 Pa时拉制的N型单晶硅氧含量最低,电池端同心圆比例也是最低的。本文研究结果可为N型单晶硅棒降氧提供一定思路。

LF精炼过程中通电升温阶段底吹氩方式的优化

在LF(ladle furnace)精炼过程的通电升温阶段多采用双喷嘴等流喷吹的吹氩方式.本文提出一种双喷嘴差流吹氩的底吹方式,以某钢厂135 t钢包为原型设计1∶4非等温水模型实验平台,在总流量相同的情况下进行底吹比例为1∶1,2∶1和3∶1的温度均匀化实验,结果表明底吹比例为2∶1时的各监测点无量纲温差最小,均匀化效果最好.建立流动-传热耦合数学模型对实验结果进行验证,结果表明在总流量相等的情况下,底吹比例为1∶1,2∶1和3∶1时流动死区占比分别为14.1%,9.1%和9.8%,温度死区占比分别为6.2%,2.6%和0.3%,2∶1差流底吹方式在活跃流场和促进温度均匀化方面具有优势.

空分设备国产化技术改造总结

马钢气体公司全套35000 m^(3)/h空分设备均自国外引进,因膨胀机、工艺液氧泵、粗氩循环泵原设计因素,精馏系统制冷量不足,工艺液氧泵、粗氩循环泵无法自动调节负荷。通过对膨胀机、工艺液氧泵、粗氩循环泵实施国产化技术改造,增加精馏系统制冷量,使工艺液氧泵、粗氩循环泵能够自动调节其出口压力。文章叙述了膨胀机、工艺液氧泵、粗氩循环泵运行存在的问题和技术改造的具体方法。

Physical and Mathematical Modeling of the Argon-Oxygen Decarburization Refining Process of Stainless Steel

The available studies in the literature on physical and mathematical modeling of the argon oxygen decarburization (AOD) process of stainless steel have briefly been reviewed. The latest advances made by the author with his research group have been summarized. Water modeling was used to investigate the fluid flow and mixing characteristics in the bath of an 18 t AOD vessel, as well as the 'back attack' action of gas jets and its effects on the erosion and wear of the refractory lining, with sufficiently full kinematic similarity. The non rotating and rotating gas jets blown through two annular tuyeres, respectively of straight tube and spiral flat tube type, were employed in the experiments. The geometric similarity ratio between the model and its prototype (including the straight tube type tuyeres) was 1:3. The influences of the gas flow rate, the angle included between the two tuyeres and other operating parameters, and the suitability of the spiral tuyere as a practical application, were examined. These latest studies have clearly and successfully brought to light the fluid flow and mixing characteristics in the bath and the overall features of the back attack phenomena of gas jets during the blowing, and have offered a better understanding of the refining process. Besides, mathematical modeling for the refining process of stainless steel was carried out and a new mathematical model of the process was proposed and developed. The model performs the rate calculations of the refining and the mass and heat balances of the system. Also, the effects of the operating factors, including adding the slag materials, crop ends, and scrap, and alloy agents; the non isothermal conditions; the changes in the amounts of metal and slag during the refining; and other factors were all considered. The model was used to deal with and analyze the austenitic stainless steel making (including ultra low carbon steel) and was tested on data of 32 heats obtained in producing 304 grade steel in an 18 t AOD vessel. The changes in the bath composition and temperature during the refining process with time can be accurately predicted using this model. The model can provide some very useful information and a reliable basis for optimizing the process practice of the refining of stainless steel and control of the process in real time and online.

分离打拿极电子倍增器性能提升技术研究

研究了磁控溅射法制备二次电子发射薄膜过程中氩气与氧气流量比和打拿极极间分压方式对电子倍增器增益及衰减特性的影响。研究表明,采用25∶5的氩气与氧气流量比所制备的MgO/(MgO-Au)双层结构薄膜具有最大的二次电子发射系数(SEY)和最小的SEY衰减率,同时利用该薄膜制作的九级打拿极电子倍增器具有最高的增益和最小的增益衰减率,这与该薄膜拥有最大的MgO晶粒尺寸和合适的导电性密切相关;采用第九打拿极与地之间的分压电阻阻值为3 MΩ且前八级打拿极极间分压电阻阻值均为6 MΩ的打拿极极间差异化分压方式制作电子倍增器能够提高器件增益,降低器件工作电压,并减缓在电子持续轰击下的增益衰减。该研究结果对高性能分离打拿极电子倍增器研制及其应用具有重要意义。

在相对真空下含CaSi_(2)的预制球团还原提镁动力学

在相对真空下以CaSi_(2)为还原剂进行预制球团提镁过程的研究。利用扫描电子显微镜(SEM)、能谱仪(EDS)和X射线衍射仪(XRD)分别对还原渣的形貌、化学成分和物相进行分析。结果表明,小的氩气流量可以极大地提高氧化镁的还原率,在相对真空下以CaSi_(2)为还原剂的预制球团提镁过程可以用F_(1)模型解释,CaSi_(2)还原氧化镁为固液反应,此过程为化学反应控制,温度对还原率影响很大,表观活化能为108.99 k J/mol。还原渣的物相分析表明,渣中的MgO含量对Ca_(2)SiO_(4)的晶型转变有影响。

核电用超纯奥氏体不锈钢316H电渣重熔氢含量控制

为研究电渣重熔过程氢含量控制影响因素,电渣重熔生产Φ590 mm电渣锭时试验了4种不同组成的电渣渣系,同时电渣重熔过程配合氩气保护。通过试验不同渣系组成及不同氩气流量下保护气氛,最终确定电渣重熔在w(CaF_(2))∶w(Al_(2)O_(3))∶w(CaO)=60%∶30%∶10%组成渣系下,采用40 L/min的氩气流量控制,可使Φ590 mm电渣锭成品氢含量控制在5×10^(-4)%以下。

提高RH生产效率实践

为了解决RH处理时间较长与铸机生产节奏不匹配的问题,对RH真空精炼设备进行升级改造,通过采取增加环流支管个数及内径和提升真空泵抽气能力等措施,确定了最优工艺参数,生产实施后RH作业时间平均缩短了约7.7 min,提高了RH真空精炼工序的生产效率,保证了生产的顺行。

中间包感应加热与吹氩协同控制工艺数值模拟

中间包采用感应加热与吹氩协同控制工艺有望实现高效去夹杂及低过热度浇铸。针对该工艺,并结合国内某钢厂的感应加热中间包建立三维非稳态数学模型,研究其磁场的分布规律,并对比分析了有无吹氩及吹气量对其流场、温度场以及夹杂物去除的影响。结果表明:感应加热中间包内偏心电磁力最小值偏离通道几何中心10 mm,沿通道径向距线圈较近位置焦耳热略有增加。吹氩使感应加热中间包内钢液在气幕两侧各形成一个循环流,消除了中间包角部流动不活跃的小循环流;且浇注区温度分布更均匀;与无吹氩感应加热中间包相比,吹氩后夹杂物去除率增大了0.4倍,有更好的去夹杂效果。吹气量在10~40 L/min时,靠近通道一侧下方存在流速较小的小循环流;当吹气量增至55 L/min时,浇注区内开始形成稳定的气幕,并在其两侧各形成一个循环流;就本研究而言,55 L/min的吹气量有最佳的控流及去夹杂效果。

LF精炼过程非金属夹杂物控制研究

钢中常见的非金属夹杂物以硫化物、氧化物等为主,主要在LF精炼工序处理去除。为了达到生产洁净钢的目的,针对硫化物、氧化物产生的原因和控制方法进行分析研究,并采取相应措施。转炉吹炼终点温度控制在1620~1635℃、终点C质量分数控制在0.08%~0.12%范围内。优化LF精炼各阶段的氩气流量,大大降低了精炼过程吸气程度,保证了夹杂物的去除;将LF炉静吹时间控制在10min即可满足净化钢液的目的;利用钙处理对夹杂物进行球化改性处理,通过保证软吹时间和氩气气量促进了夹杂物的上浮。

氮氩体积流量比对AlN薄膜生长取向、晶体质量及沉积速率的影响及机理分析

采用反应磁控溅射法,在溅射气压、溅射功率和衬底温度恒定的条件下,通过调控氮氩体积流量比,在单晶Si衬底上制备AlN薄膜。利用X射线衍射仪(XRD)、原子力显微镜(AFM)和场发射扫描电子显微镜(FESEM)研究氮氩体积流量比对AlN薄膜的生长取向、晶体质量及沉积速率的影响规律并分析其机理。结果显示,提高氮氩体积流量比有利于AlN薄膜(002)择优取向的生长,但过高的氮氩体积流量比会降低薄膜的沉积速率。在溅射气压为5 mTorr(1 Torr=133.3 Pa)、溅射功率为500 W、衬底温度为200℃、氮氩体积流量(cm3/min)比为14∶6时,在单晶Si衬底上可以制备出质量较好的,具有良好(002)择优取向的AlN薄膜。研究结果可为反应磁控溅射制备高质量AlN薄膜提供工艺参数设置规律指导。

磁控溅射氧氩体积流量比对β-Ga_(2)O_(3)薄膜的影响

利用射频磁控溅射在c面单晶蓝宝石(Al_(2)O_(3))衬底上制备Ga_(2)O_(3)薄膜,研究了溅射过程中通入氧气与氩气的体积流量比对经过异位高温后退火处理得到的β-Ga_(2)O_(3)薄膜特性的影响。利用X射线衍射仪(XRD)和原子力显微镜(AFM)对薄膜进行表征,结果表明β-Ga_(2)O_(3)薄膜沿着■晶面择优生长,具备较好的单一取向性。在氧氩体积流量比约为1∶20时,薄膜的结晶性能相对较好、表面晶粒分布较均匀、均方根粗糙度较小、晶粒尺寸较大。此外,吸收光谱表征结果表明,不同氧氩体积流量比下制备得到的β-Ga_(2)O_(3)薄膜的带隙变化范围为4.53~4.64 eV,在较低氧氩体积流量比下制备的β-Ga_(2)O_(3)薄膜表现出较优的光学性质,在波长200~300 nm内具有较好的吸收特性,表现出良好的深紫外光学特性。

30t钢包偏心单吹流场的数值模拟

利用连续性方程、动量方程、Navier-Stokes方程、欧拉方程和k-ε双方程,运用Fluent软件的Simple算法,气液两相区采用欧拉两相流模型进行稳态下的钢包流场计算,得到了不同喷吹量及偏心位置不同时单孔吹气时,钢包内的流场三维分布图。首先通过偏心单吹死区比例的计算和流场的变化规律,确定最优单吹方案为包底0.55R处、气量为60 NL/min,然后对最优偏心单孔进行不同吹气量的流场数值模拟计算,得出钢包纵截面的流场分布图,分析发现吹气量的增加仅让钢包内钢液流动的速度提高了,但钢液的流动形态并未改变,大约在钢包的4/5高度处形成涡心,涡流运动十分明显。