三氯化铁-草酸体系不锈钢化学机械抛光液设计与优化

为提高柔性显示衬底不锈钢箔片化学机械抛光加工效率,研制一种三氯化铁-草酸型抛光液并用于304不锈钢衬底的化学机械抛光加工过程。设计正交优化试验,确定磨粒粒径、磨料含量、草酸含量和三氯化铁含量对材料去除率和表面粗糙度(S_(a))的影响显著性顺序,并重点探究三氯化铁和草酸对材料去除率的影响规律。利用优化后的抛光液精抛304不锈钢,其材料去除率高于560 nm/min,抛光30 min后Sa低于8 nm。相比现有抛光液的材料去除效率(226.56 nm/min),新抛光液的加工效率提升超过1倍。

节镍不锈钢的开发与展望

近年全球镍金属价格上涨,不锈钢节镍非常必要。节镍不锈钢主要有铁素体不锈钢,Cr-Mn-Ni-N奥氏体不锈钢与含N的双相不锈钢。重点对超铁素体不锈钢与新型Cr-Mn-Ni-N奥氏体不锈钢与节镍双相不锈钢作了介绍。

Effect of Fe2O3 on the size and components of spinel crystals in the CaO–SiO2–MgO–Al2O3–Cr2O3 system

size of spinel crystals in the CaO–SiO2–MgO –Al2O3–Cr2O3 system was investigated using lab experiments carried out in a carbon tube furnace. Scanning electron microscopy with energy-dispersive X-ray spectroscopy（SEM–EDS） and X-ray diffraction（XRD） were used to analyze the microstructure, components, and the mineral phases of synthetic slags. FactS age 7.1 was used to calculate the crystallization process of the molten slag. The results showed that the addition of Fe2O3 promoted the precipitation of spinel crystals and inhibited the formation of dicalcium silicate. The size of spinel crystals increased from 2.74 to 8.10 μm and the contents of chromium and iron in the spinel varied as the Fe2O3 addition was increased from 0 to 20 wt%. Fe2O3 thermodynamically provided the spinel-forming components to enhance the formation of FeCr2O4, MgFe2O4, and Fe3O4. The addition of Fe2O3 increased the fraction of liquid phase in a certain temperature range and promoted diffusion by decreasing the slag’s viscosity. Therefore, Fe2O3 is beneficial to the growth of spinel crystals in stainless steel slag.

430不锈钢板坯横裂成因分析及控制措施

通过对430不锈钢连铸板坯存在横裂缺陷的试样进行低倍检验、金相检验及韧脆转变温度测定,确定铁素体晶界上大量的碳化物析出相加速裂纹的扩展,致使铸坯更容易发生脆性断裂。提出相应的工艺控制措施:提高铸机的对弧精度,足辊出口对弧精度为0.5mm,零段出口对弧精度为0.33 mm,一段出口对弧精度为0.27mm;板坯在500℃附近快速冷却,避免脆性相的产生;要求wC+wN小于0.03%;铸坯采用带温修磨,修磨温度控制到120℃以上,1周内完成铸坯的转序、轧制。对优化工艺进行工业试验得出,430板坯横裂缺陷得到了有效控制,杜绝了因板坯横裂引起的热轧断带事故及钢带孔洞缺陷,工艺措施效果显著。

盐酸基溶液中铁离子对铁素体不锈钢腐蚀行为的影响

通过腐蚀失重测试、宏观形貌观察、微观形貌分析、自腐蚀电位测定、极化曲线以及交流阻抗图谱测试等试验检测方法,考察了盐酸溶液中铁离子对热轧抛丸后铁素体不锈钢表面氧化层去除过程的影响。结果表明:不锈钢酸洗过程中Fe2+的累积使溶液氧化还原电位降低,同时降低酸洗效率;Fe3+的累积使溶液氧化还原电位提升,同时提升酸洗效率。在3 mol/L盐酸浓度的溶液中,加入0.5 mol/L的Fe3+或Fe2+,不锈钢的酸洗失重率由0.22%分别增至1.23%或降至0.14%。随着溶液中Fe3+同Fe2+摩尔浓度比(CFe3+/CFe2+)的增大,不锈钢的酸洗失重率逐渐增大。在盐酸浓度为1.37 mol/L、全铁浓度为1.79 mol/L的溶液体系中,当CFe3+/CFe2+≥2时,不锈钢的酸洗失重率较不含铁离子的溶液体系提高7.2倍以上。在盐酸溶液中,Fe3+通过直接参与阴极反应提升反应速率,Fe2+通过替换不锈钢表面吸附的H+从而降低反应速率。