Effects of sphere size on the microstructure and mechanical properties of ductile iron–steel hollow sphere syntactic foams

The effects of sphere size on the microstructural and mechanical properties of ductile iron–steel hollow sphere（DI–SHS） syntactic foams were investigated in this study. The SHSs were manufactured by fluidized-bed coating via the Fe-based commercial powder–binder suspension onto expanded polystyrene spheres（EPSs）. Afterwards, the DI–SHS syntactic foams were produced via a sand-mold casting process. The microstructures of specimens were investigated by optical microscopy, scanning electron microscopy（SEM）, and energy-dispersive X-ray spectroscopy（EDS）. The microscopic evaluations of specimens reveal distinct regions composed of the DI matrix, SHS shells, and compatible interface. As a result, the microstructures and graphite morphologies of the DI matrix depend on sphere size. When the sphere size decreases, the area fractions of cementite and graphite phases are observed to increase and decrease, respectively. Compression tests were subsequently conducted at ambient temperature on the DI–SHS syntactic foams. The results reveal that the compression behavior of the syntactic foams is enhanced with increasing sphere size. Furthermore, the compressed specimens demonstrate that microcracks start and grow from the interface region.

Effect of vibration frequency on primary phase and properties of grey cast iron fabricated by lost foam casting

The properties of gray cast iron(GCI)are affected by density of matrix,size of flake graphite and primary austenite.In this paper,the Y-type specimen of GCI was prepared by lost foam casting(LFC)with and without vibration,and the influence of vibration frequency on the density of matrix,size of primary phase,and properties of the GCI was studied.The results show that the length of the flake graphite and the size of the primary austenite in GCI firstly decrease and then increase with the increase of the vibration frequency.With a vibration frequency of 35 Hz,the length of the flake graphite is the shortest,the primary austenite is the finest and the density of the matrix is the highest.In addition,the tensile strength,elongation and hardness of the GCI firstly increase and then decrease with the increase of the vibration frequency,due to the refinement of the primary phase and the increase of the matrix density.In order to analyze the refinement mechanism of the primary phase of the GCI fabricated by the LFC with vibration,the solidification temperature fields of the GCI fabricated by the LFC with the vibration frequency of 0 and 35 Hz were measured.The results show that the vibration reduces the eutectic point of the GCI and increases the supercooling degree during the eutectic transformation.As a result,the length of the flake graphite and the size of the primary austenite in GCI fabricated by LFC with the vibration frequency of 35 Hz decrease.

Construction and analysis of dynamic solidification curves for non-equilibrium solidification process in lost-foam casting hypoeutectic gray cast iron

Most lost-foam casting processes involve non-equilibrium solidification dominated by kinetic factors, while construction of a common dynamic solidification curve is based on pure thermodynamics, not applicable for analyses and research of non-equilibrium macro-solidification processes, and the construction mode can not be applied to nonequilibrium solidification process. In this study, the construction of the dynamic solidification curve(DSC) for the nonequilibrium macro-solidification process included: a modified method to determine the start temperature of primary austenite precipitation(T_(AL)) and the start temperature of eutectic solidification(T_(ES)); double curves method to determine the temperature of the dendrite coherency point of primary austenite(T-(AC)) and the temperature of eutectic cells collision point(T_(EC)); the "technical solidus" method to determine the end temperature of eutectic reaction(T_(EN)). For this purpose, a comparative testing of the non-equilibrium solidification temperature fields in lost-foam casting and green sand mold casting hypoeutectic gray iron was carried out. The thermal analysis results were used to construct the DSCs of both these casting methods under non-equilibrium solidification conditions. The results show that the transformation rate of non-equilibrium solidification in hypoeutectic gray cast iron is greater than that of equilibrium solidification. The eutectic solidification region presents a typical mushy solidification mode. The results also indicate that the primary austenite precipitation zone of lost-foam casting is slightly larger than that of green sand casting. At the same time, the solid fraction(f_s) of the dendrite coherency points in lost-foam casting is greater than that in the green sand casting. Therefore, from these two points, lost-foam casting is more preferable for reduction of shrinkage and mechanical burntin sand tendency of the hypoeutectic gray cast iron. Due to the fact that the solidification process(from the surface to center) at primary austenite growth area in the lost-foam cylinder sample lags behind that in the green sand casting, the mushy solidification tendency of lost-foam casting is greater and the solidification time is longer.

Study on Foaming Behaviour of Molten Slag during Smelting Reduction with Iron Bath

The molten slag in smelting reduction with iron bath has peculiar behaviour for its high FeO concentration. Slag foaming is effected by the concentration and reduction rate of FeO, basicity of slag and temperature. Addition of granulated coke can greatly decrease slag foaming extent in the process of smelting reduction with iron bath. The anti-foaming capacity of granulated coke is the best when the ratio of coke used for coke layer to total coke used in smelting reduction is controlled at about 20%.

High Cr white cast iron/carbon steel bimetal liner by lost foam casting with liquid-liquid composite process

Liners in wet ball mill for mineral processing industry must bear abrasive wear and corrosive wear, and consequently,the service life of the liner made from traditional materials,such as Hadfield steel and alloyed steels,is typically less than ten months.Bimetal liner,made from high Cr white cast iron and carbon steel,has been successfully developed by using liquid-liquid composite lost foam casting process.The microstructure and interface of the composite were analyzed using optical microscope,SEM,EDX and XRD.Micrographs indicate that the boundary of bimetal combination regions is staggered like dogtooth,two liquid metals are not mixed,and the interface presents excellent metallurgical bonding state.After heat treatment,the composite liner specimens have shown excellent properties,including hardness>61 HRC,fracture toughnessα k >16.5 J·cm-2 and bending strength >1,600 MPa.Wear comparison was made between the bimetal composite liner and alloyed steel liner in an industrial hematite ball mill of WISCO,and the results of eight-month test in wet grinding environment have proved that the service life of the bimetal composite liner is three times as long as that of the alloyed steel liner.

铁尾砂泡沫混凝土的制备及性能

以铁尾砂为细骨料,采用不同掺量的铁尾砂取代天然砂制备目标密度为900 kg/m~3的铁尾砂泡沫混凝土试件,分析铁尾砂掺量对试件干燥收缩率、吸水率、导热系数、抗压强度、劈裂抗拉强度等性能的影响;并采用扫描电镜及图象分析软件分析试件的微观形貌。结果表明:铁尾砂掺量(质量分数)在0~40%范围内,随铁尾砂掺量的增加,泡沫混凝土的干燥收缩率和吸水率下降,导热系数略有增加;泡沫混凝土的抗压强度和劈裂抗拉强度呈先增后减的趋势,铁尾砂掺量20%时抗压和劈裂抗拉强度最高;掺入适量的铁尾砂可改善泡沫混凝土的孔结构,内部孔径趋向均匀,铁尾砂质量分数超过20%时泡沫混凝土的微观结构劣化,这也是导致其力学性能开始下降的原因。

铁超载调控氧化性低密度脂蛋白诱导泡沫细胞促动脉粥样硬化活化的作用

目的探讨铁超载对泡沫细胞促动脉粥样硬化(AS)活化的影响。方法RAW264.7和MOVAS细胞株扩增培养,分为正常对照(media)组、oxLDL组、oxLDL+柠檬酸铁铵(oxLDL+FC)组、oxLDL+柠檬酸铁铵+去铁胺(oxLDL+FC+DFO)组,分别以氧化性低密度脂蛋白(oxLDL)、柠檬酸铁胺(FC)、去铁胺(DFO)刺激。普鲁士蓝和油红O染色检测铁沉积和泡沫细胞生成。CCK-8测定细胞存活率,DHE探针观察活性氧自由基(ROS)生成,ELISA测定还原型谷胱甘肽(GSH)、谷胱甘肽过氧化物酶4(GPX4),丙二醛(MDA)含量。RT-qPCR检测ATP结合盒转运体A1(ABCA1)和ATP结合盒转运体G1(ABCG1)、诱导型一氧化氮合酶(iNOS)、精氨酸酶1(Arg-1)、平滑肌肌动蛋白(α-SMA),平滑肌22a(smooth muscle 22 alpha,SM22a)、骨桥蛋白(OPN),白细胞介素-1β(IL-1β)、肿瘤坏死因子-α(TNF-α)mRNA表达。结果与oxLDL组相比,oxLDL+FC组细胞胆固醇逆向转运分子ABCA1和ABCG1表达降低,细胞泡沫化加重,死亡率上升,且ROS和MDA的表达增加,GPX4表达降低,巨噬细胞M1型标志物及平滑肌细胞合成型标志物升高,炎症因子IL-1β、TNF-α的表达明显增加,差异有统计学意义(P<0.05)。结论铁超载能促进泡沫细胞生成,使其向促动脉粥样硬化表型转化,加重脂质过氧化及炎症反应。

低硅铁尾矿制备轻质泡沫混凝土试验研究

为解决低硅铁尾矿堆存量大、利用困难等问题,以杨家湾尾矿库内低硅铁尾矿为矿物掺和料,水泥为胶凝材料,Al粉为发泡剂,制备轻质泡沫混凝土,并考察了水泥掺量、水料比、发泡剂Al粉掺量、激发剂CaO掺量等因素对泡沫混凝土性能的影响。结果表明:在铁尾矿掺量55%、Al粉掺量0.14%、CaO掺量5%、聚丙烯纤维掺量0.3%、稳泡剂掺量0.25%、水料比0.55的条件下,经20±1℃恒温恒湿养护28d,可制备出抗压强度1.84MPa、干密度768.61kg/m^(3)、比强度2.394×10^(-3)Nm/kg的轻质泡沫混凝土,综合性能良好,符合JG/T266—2011《泡沫混凝土》之A08干密度等级、C1强度等级要求。机理分析表明:孔隙率的过度提高会破坏制品内部的孔隙结构,对制品强度造成负面影响;铁尾矿的添加有助于混匀料浆,促进Ca(OH)2的生成,为料浆进一步创造碱性环境,促进钙矾石、C—S—H凝胶等水化产物的生成,其与铁尾矿的交织分布会支撑起孔隙结构,改善力学结构,使泡沫混凝土即使在较低密度下仍表现出较好的力学性能。

造孔剂法制备泡沫铁及其性能研究

本文选择了一种新型造孔剂Na_(2)S_(2)O_(3)·5H_(2)O(五水硫代硫酸钠),用该造孔剂制备出了孔径分别为2mm、3mm和4mm,孔隙率60%和70%的泡沫铁;并对孔径为2mm、3mm和4mm以及孔隙率为60%和70%的泡沫铁进行了力学性能与吸能性试验。结果表明,用新型造孔剂Na_(2)S_(2)O_(3)·5H_(2)O制备的泡沫铁,结构可控;孔径、孔隙率和烧结温度都对泡沫铁的性能有不同程度的影响,在本试验参数下孔径为2 mm,孔隙率为60%,烧结温度为1150℃时,具有最佳的吸能性能和力学性能。

高钙铁尾矿对多孔陶瓷烧结温度和性能的影响

为促进矿业固废铁尾矿的高值化利用,以高钙铁尾矿作为主要原料,高岭土为黏结剂,石英作为骨料,碳化硅为发泡剂,采用“注浆成型-直接发泡法”制备高孔隙率铁尾矿多孔陶瓷,并通过测试多孔陶瓷孔隙率、孔径分布、体积密度和抗压强度,研究铁尾矿用量对多孔陶瓷烧结温度及性能结构的影响。结果表明,高钙铁尾矿可作为助熔剂使用,在原料配比为40%铁尾矿,20%高岭土、40%石英,外加0.3%碳化硅,烧结温度在1160~1170℃的条件下所制备的多孔陶瓷各项性能最优,其体积密度密度为0.38~0.46 g/cm^(3),气孔率高达80.84%~83.5%,平均孔径为0.33~0.88 mm,抗压强度为1.95~3.28 MPa。微观分析表明,铁尾矿内的方解石高温下分解产生的CaO可以与原料中的SiO_(2)反应生成钙长石,并大幅度降低材料的烧结温度和液相黏度,同时铁尾矿中的方解石和Fe_(2)O_(3)可以促进气泡的增长,有利于进一步提高气孔率。

主轴箱铸件的消失模铸造工艺优化

介绍了主轴箱铸件的结构及技术要求,针对主轴箱铸件的碳缺陷问题,从浇注系统设计、冒口、集渣条设计和埋箱造型方式等3个方面入手,对主轴箱铸件的消失模铸造工艺进行优化设计。经实际生产验证,通过优化浇注系统机构,更改造型方式,增加出气系统,可以有效消除铸件的碳缺陷问题,铸件无夹砂、夹渣等铸造缺陷,铸件尺寸精度高,质量稳定,满足技术要求,铸件的合格率达到95%以上。

CoFe-LDH/泡沫铜的制备及催化介质阻挡放电等离子体降解水中敌草隆性能与机制

采用一步水热法,以钴和铁元素为活性组分制备了片层状钴铁层状双金属氢氧化物(CoFe-LDH),通过调节元素摩尔比和水热温度、时间以及尿素投加量的制备条件得到了可以高效催化介质阻挡放电等离子体(DBDP)的粉末催化剂。研究结果表明,当n(尿素)∶n(Co)∶n(Fe)=10∶3∶1,水热温度为120℃,水热时间18 h时,得到的CoFe-LDH催化性能最优,其催化DBDP降解敌草隆(DUR)的降解率和降解速率常数分别达到了96.54%和0.1354 min^(-1),制备条件中水热时间对催化性能影响最大。在此基础上,将配比优化的CoFe-LDH负载在泡沫铜(CuF)表面,得到了片状可回收的三元CoFe-LDH/CuF(CFHC)催化剂。系统地表征了CFHC的结构组成,研究了微观结构和元素组成与催化性能之间的内在联系。由于还原态铜元素的引入,增加了催化剂表面的氧空位含量,显著地提升了复合材料的催化性能。CFHC的加入成功将DBDP对敌草隆的去除速率提升至0.2175 min^(-1),是DBDP空白体系的3.18倍。CuF的引入增加了催化剂的导电能力,在降解过程中钴、铁、铜和氧空位之间的电子转移是高催化活性的根本原因,CFHC重新调整了DBDP体系内的优势活性物种,·O_(2)^(-)和^(1)O_(2)取代·OH成为了降解敌草隆的主要活性物质。

碱激发铁尾矿泡沫混凝土的制备及其性能

为了资源化利用铁尾矿,以铁尾矿、粉煤灰、矿渣为原料,通过碱激发胶凝材料部分替代水泥制备泡沫混凝土,分析了碱激发胶凝材料、泡沫、水胶比、聚乙烯醇等对泡沫混凝土抗压强度和导热系数的影响,并利用电镜扫描、X射线衍射分析其微观结构及反应机理。结果表明,当碱激发胶凝材料掺量为40%、水胶比为0.40、聚乙烯醇为1%时,28 d最大抗压强度为4.99 MPa,干表观密度为784 kg/m^(3),导热系数为0.1909 W/(m·K),满足规范要求。

多孔材料对氢气爆轰的抑制作用

为了研究多孔材料对氢气爆轰的抑制作用,在内径80 mm、长6000 mm的爆轰圆管中开展2H_(2)+O_(2)+3Ar预混气爆轰传播实验。在距点火头5000 mm处放置不同孔隙密度(10、20、40 ppi)厚度30 mm的Al_(2)O_(3)泡沫陶瓷和不同厚度(10、30、50 mm)孔隙密度20 ppi的泡沫铁镍金属,分别使用压力传感器、烟膜记录爆轰波压力、胞格结构,计算爆轰波传播速度。结果表明,速度亏损和胞格尺寸随着孔隙密度或厚度的增加而增大,但是均与初始压力成反比。两种多孔材料的材料特性不同,泡沫铁镍金属具有良好的导热性,因此对爆轰波的抑制效果强于Al_(2)O_(3)泡沫陶瓷。

Phosphorus Adsorption and Nitric Acid Reduction by Ferrous Sulfate-Treated Foamed Waste Glass

Wastewaters containing phosphorus and nitric acid are produced during biological treatment processes. In this study, a material for treating such wastewaters was developed. Foamed glass was produced from waste glass and then heated with iron sulfate to prepare an adsorbent for phosphorus and carrier for reducing nitric acid. The adsorbent performance was evaluated in batch and continuous experiments. The saturated adsorption amount of phosphate was 6.23 mg/g for the product obtained from glass of size 3 to 12 mm;the amount adsorbed was relatively high, in spite of the large glass size. The denitrification by reduction of nitrate was around 25%.

镍铁双金属催化剂的制备及其催化甲烷裂解性能评价

催化甲烷裂解(CMD)可产出不含COx的氢气和高附加值的炭材料,是一种潜在的环境友好型制氢工艺。为了开发一种高效的CMD催化剂,以泡沫镍和Fe(NO3)3·9H2O为前驱体、MgO粉末作为载体,采用熔融法制备了镍铁双金属催化剂。考察了双金属负载比例、焙烧温度(550~850℃)和CMD反应温度(600~850℃)对镍铁双金属催化剂的CMD反应催化性能的影响。结果表明,当镍和铁的负载量(质量分数)分别为11%和25%,焙烧温度为600℃时,所得催化剂在850℃下的CMD反应中表现出良好的催化活性和稳定性,甲烷转化率达94%以上。采用塔曼温度分析了镍铁双金属催化剂的形成过程及镍铁双金属之间的潜在协同作用,并利用柯肯达尔效应解释了形成的积炭形态和催化剂的潜在失活原因。

铁尾砂泡沫混凝土抗冻融性能及可靠性分析

为研究铁尾砂泡沫混凝土抗冻融性能,制备了5组目标密度为900 kg/m 3的泡沫混凝土,在硫酸盐环境下冻融循环后,对比分析不同铁尾砂掺量泡沫混凝土的质量损失、强度损失、孔隙面积率和微观结构。以质量损失和强度损失为衡量指标,评选最优配合比,基于Wiener退化过程进行可靠度分析并预测剩余寿命。结果表明:在硫酸盐冻融循环过程中,泡沫混凝土表面损伤,内部孔隙连通形成裂缝,各试件质量呈先增加后减少的趋势;抗压强度和孔隙面积率持续下降,细粒径铁尾砂的掺入有效缓解了泡沫混凝土的损伤。其中,20%(质量分数)铁尾砂掺量的泡沫混凝土抗冻融能力最强,试件经过约300次冻融循环后失效。本研究可为泡沫混凝土在冻土地区的应用提供思路。

铁尾矿及其反应烧结多孔陶瓷的制备与性能研究

为拓展铁尾矿的资源化利用途径,本研究分别以细颗粒高硅铁尾矿、铁尾矿+石墨粉以及铁尾矿+石墨粉+碳化硅粉为原料,采用泡沫注凝成形-常压烧结、泡沫注凝成形-反应烧结和模压成形-反应烧结工艺制备了铁尾矿多孔陶瓷和三种以碳化硅为主晶相的多孔陶瓷。通过DSC-TG和XRD分析,研究了铁尾矿自身的烧结过程以及铁尾矿与石墨之间的碳热还原反应烧结过程,对比分析了四种多孔陶瓷材料的孔隙率、压缩强度、热导率等性能。结果表明,以铁尾矿为原料可制备具有较高孔隙率(87.2%)、压缩强度(1.37 MPa)和低热导率(0.036 W/(m·K))的铁尾矿多孔陶瓷,它是一种高效保温隔热材料;利用铁尾矿与石墨之间的碳热还原反应可获得碳化硅多孔陶瓷,其热导率显著提高,但强度偏低;而在原料中加入部分碳化硅,可以明显改善多孔陶瓷的压缩强度,获得具有高孔隙率(91.6%)、较高压缩强度(1.19 MPa)和热导率(0.31 W/(m·K))的碳化硅多孔陶瓷,它可作为轻质导热材料或复合相变材料的载体使用;与泡沫注凝成形工艺相比,采用模压成形工艺制备的碳化硅多孔陶瓷虽然孔隙率有所降低(79.3%),但热导率得到显著提升(1.15 W/(m·K)),同时原料和生产成本大幅降低,有利于实现产品的工业化生产。

泡沫镍上原位制备FeOOH/MoSe_(y)及电解水双催化性能研究

为设计同时具有优异电催化析氢和析氧性能的过渡金属基催化剂,以泡沫镍为载体和集流体,原位制备了硒化钼(MoSe_(y))和羟基氧化铁(FeOOH),得到FeOOH/MoSe_(y)@Ni复合材料。表征结果表明,先通过电沉积法原位生长了MoSe_(y)层,再以该MoSe_(y)层为成核点,通过常温浸泡生长形成了由FeOOH纳米片组成的微米绒球。在三电极体系中,以1 mol·L^(-1) KOH溶液为电解液,该FeOOH/MoSe_(y)@Ni复合材料表现出优异的电催化析氢和析氧性能,析氢电流密度在10 mA·cm^(-2)时的过电位(η_(10))为128 mV,析氧电流密度在20 mA·cm^(-2)时的过电位(η_(20))为306 mV,并具有较小的Tafel斜率、较大的双电层电容(C_(dl))值和良好的稳定性。FeOOH/MoSe_(y)@Ni优异的电催化性能主要由于三维开放的泡沫镍骨架和原位制备的MoSe_(y)层和FeOOH微米绒球相结合,可提供丰富的催化活性中心、良好的导电性、离子传输以及稳定性。

球墨铸铁重型辅板的消失模试制工艺

介绍了球墨铸铁重型辅板铸件的结构及技术要求,详细阐述了该铸件的生产工艺:采用半开放式浇注系统、倾斜侧浇工艺,在铸件的顶部设置溢流冒口,吸纳充型过程中前沿的低温铁液,消除铸件顶部表面积碳或皱皮;采用共聚料STMMA3A#材料进行珠粒预发泡,选用新型SZ-1型消失模干粉涂料进行涂料混制,波美度控制在63~65°Bé。生产结果显示:铸件外形轮廓清晰,表面没有出现渣孔、皱皮类铸造缺陷,内浇道位置没有出现缩孔缺陷,重型辅板轮缘的不平整度<3 mm,铸件加工后,加工面没有出现黑皮,铸件的整体质量达到了技术要求。