Effect of BaO addition on electric conductivity of xCu/10NiO-NiFe2O4 cermets

The effects of BaO addition on the phase composition, relative density and electric conductivity of xCu/10NiO-NiFe2O4 （x=5, 10） eermets were studied, which were prepared with cold isostatic pressing-sintering process. The results show that the relative densities of 5Cu/10NiO-NiFe2O4 cermet doped with 1% BaO （mass fraction） and 10Cu/10NiO-NiFe2O4 cermet doped with 1% BaO sintered at 1 473 K in nitrogen atmosphere, are increased by about 9.86% and 9.75% compared with the undoped BaO cermets, respectively. And the electric conductivities 22.79 S/cm of 5Cu/10NiO-NiFe2O4 cermets adding 1% BaO and 23.10 S/cm of 10Cu/10NiO-NiFe2O4 cermets adding 1% BaO are obtained, which are 2.21 times and 1.47 times of those of undoped samples, respectively. Moreover, the 10Cu/10NiO-NiFe2O4 cermets doped with 1% BaO have a maximum σ0 of 58.91 S/cm and electric conductivity of 23.10 S/cm at 1 233 K. Maybe low melting-point phases of BaFe2O4 and Ba2Fe2O5 have an excellent electric conductivity in xCu/10NiO-NiFe2O4 （x=5, 10） cermets at 1 233 K.     

镍基惰性阳极的耐腐蚀性研究(上)

论述NiO-NiFe2O4基金属陶瓷惰性阳极在熔融电解质中的腐蚀情况，对该镍基惰性阳性的制备过程及抗腐蚀性能进行了深入研究。     

铁酸镍基金属陶瓷的强化烧结与熔盐腐蚀行为

采用气氛烧结方法制备NiFe2O4基金属陶瓷材料,并进行960℃的铝电解腐蚀实验.通过分析烧结体的显微结构和物相组成、电解试样的表层形貌与成分以及电解质和阴极铝的杂质含量等,研究BaO、Yb2O3和CoO的添加以及金属相的组成对NiFe2O4基金属陶瓷烧结性能的影响;表征J该金属陶瓷强化烧结体作为铝电解惰性阳极的电解腐蚀性能;并对材料强化烧结机制和熔盐腐蚀行为进行探讨.结果表明烧结过程中,BaO和Yb2O3与该金属陶瓷中的陶瓷相反应生成新的物相,CoO与陶瓷相形成固溶体,并加快烧结致密化进程;以Cu-Ni取代纯Cu和纯Ni作为金属陶瓷的金属相,可提高材料的相对密度;NiFe2O4基金属陶瓷的高致密度可抑制电解过程中金属相的流失和陶瓷相的腐蚀,阳极表层也转变为致密的NiFe2O4相.     

17（Cu-10Ni）-（NiFe2O4-10NiO）基金属陶瓷在铝电解过程中的相演变（英文）

采用冷压气氛烧结制备17(Cu-10Ni)-(NiFe2O4-10NiO)金属陶瓷,并作为阳极在960°C下分别进行10和40h的铝电解试验。对电解前后金属陶瓷的显微结构、物相成分进行分析检测。对电解质及阴极金属中的杂质含量进行分析,研究阳极组成中Fe、Ni和Cu元素的腐蚀行为。研究发现:在电解过程中,在材料表面形成NiFe2O4相致密层,该致密层随电解时间的延长而增厚。在NiFe2O4相致密层形成与增厚过程中,出现NiFe2O4相吞噬NiO相和金属相氧化的现象,金属陶瓷中Cu元素优先腐蚀溶解。并着重讨论NiFe2O4相致密层形成与增厚过程中金属相的腐蚀形式及NiO相向NiFe2O4相的转变机制。     

电流密度对铝电解NiFe_2O_4基金属陶瓷惰性阳极腐蚀的影响

在Na3AlF6-K3AlF6-AlF3-Al2O 3熔体中,研究电流密度对22(Ni+Cu)/(NiFe2O4-10NiO)金属陶瓷惰性阳极腐蚀速率的影响,并分析腐蚀后阳极的微观结构。结果表明,随着电流密度的升高,NiFe2O4基金属陶瓷惰性阳极腐蚀从以化学溶解腐蚀为主逐渐转变为以电化学腐蚀为主,腐蚀率先降低而后增大。当电流密度从1.0 A/cm2增大至1.6 A/cm2时,阳极年腐蚀率从1.22 cm/a降低至0.137 cm/a;进一步提高电流密度至4.0 A/cm2时,阳极年腐蚀率增大到4.96 cm/a。     

镍铁尖晶石基金属陶瓷惰性阳极的研制

采用热压烧结的方法制备了镍铁尖晶石基金属陶瓷试样,用于铝电解的惰性阳极。实验制得了相对密度大于98%的阳极试样,并研究了试样的导电性能和抗电解质腐蚀性能。结果表明,所得的阳极试样的电导率随温度的升高而增大,在900℃时电导率在40Ω-1·cm-1~60Ω-1·cm-1之间。在电解过程中,阳极电压降平稳(2.8V~3.2V),表明阳极的电阻在电解过程中没有明显变化,导电性能稳定。用反电动势法测量电解反应的分解电压为2.2V~2.5V,表明电解反应为2Al2O3=4Al+3O2,电极呈现良好的惰性。电子显微分析表明,试样抗冰晶石-氧化铝熔盐腐蚀的性能良好,电解质通过对Fe2O3的溶解来腐蚀阳极。     

BaO掺杂对10NiO-NiFe2O4复合陶瓷烧结致密化的影响

利用冷压一烧结技术制备BaO掺杂的10NiO-NiFe2O4复合陶瓷,研究BaO掺杂量及烧结温度对10NiO-NiFe2O4复合陶瓷物相组成、显微结构及致密度的影响。结果表明：当BaO掺杂量（质量分数）为0,-4％时,烧结样品中主要含NiO和NiFe2O4,BaO与10NiO-NiFe2O4陶瓷组分反应并形成瞬时液相BaFe2O4和Ba2Fe2O5,且Ba2＋固溶到基体中,促进致密化烧结,降低了烧结致密化温度;1250℃烧结时,1％BaO掺杂样品的相对密度最大,达到98．90％,比未掺杂样品的相对密度提高6．27％;但当BaO掺杂量为2％和4％时,陶瓷样品相对密度基本不变。     

铝电解用NiFe2O4-10NiO基金属陶瓷惰性阳极的耐腐蚀性能

制备铝电解用NiFe2O4-10NiO基金属陶瓷惰性阳极,并在实验室电解槽中考察其电解腐蚀性能。结果表明,电解过程中虽然惰性阳极在960°C熔盐电解质中表现出优异的耐腐蚀性能,但采用XRD、SEM/EDX和金相分析其物相组成和微观结构后发现,电解后阳极中的金属相发生了优先腐蚀,在阳极表面产生大量孔洞。NiFe2O4相中的 Fe 元素的优先溶解可能导致 NiFe2O4晶粒的不均匀腐蚀。溶解在电解液中的 Al2O3与阳极中的 NiO 或FeO 发生反应生成的 NiFe2O4-NiAl2O4-FeAl2O4相对 NiO 相的吞并以及体积膨胀,阳极表面形成致密的NiFe2O4-NiAl2O4-FeAl2O4保护层。因此,致密的NiFe2O4-NiAl2O4-FeAl2O4保护层可以阻挡阳极表面金属相的损失和陶瓷相的腐蚀。     

NiFe2O4基金属陶瓷惰性阳极腐蚀组元在电解质中的传质研究

通过计算铝电解用NiFe2 O4基金属陶瓷惰性阳极腐蚀组元Fe、Ni和Cu在铝电解质中的传质系数,讨论了不同过热度下不同阳极腐蚀组元在电解质中的传质行为.结果表明,过热度对不同腐蚀组元的影响不明显,Cu的抗腐蚀性能最好,Ni次之,而Fe最差.     

Co-Ni-xNiFe2O4惰性阳极的电导率及耐腐蚀性能

采用冷等静压-烧结的方法制备了铝电解用Co-Ni-xNiFe2O4(x=5%,10%,15%,20%,质量分数,下同)金属基惰性阳极,并对试样的导电性和抗腐蚀性进行了研究.结果表明阳极试样的电导率随NiFe2O4含量的增加和温度的升高而降低,在900℃时惰性阳极47.5Co 47.5Ni 5.0NiFe2O4和42.5Co 42.5Ni 15.0NiFe2O4的电导率分别为550 S·cm-1和300 S·cm-1.SEM照片表明试样的抗腐蚀性随着NiFe2O4含量的增加而增强.由于氧化作用和铝热反应,电解极化腐蚀速率要比静态腐蚀速率大.     

Effect of Ni content on corrosion behavior of Ni/（10NiO-90NiFe2O4） cermet inert anode

Ni/（10NiO-90NiFe2O4） cermet inert anodes with metal Ni content of 0, 5, 10, 15 and 20 （mass fraction, %） were prepared and their corrosion behavior in Na3AlF6-Al2O3 melts was investigated in laboratory electrolysis tests. The results indicate that the content of metal Ni in anodes has little effect on the steady-state concentration of impurities Ni and Fe in electrolyte and the values range in （114-173）×10^-6 and （287-385）×10^-6, but the content of impurities in the metal aluminum manifolds. There is preferential corrosion for metal Ni in NiO-NiFe2O4 based cermet anodes. Considering the corrosion resistance and electrical conductivity, the cermet containing 5%Ni （mass fraction） behaves best among NiO-NiFe2O4 based cermet anodes studied, and should be further studied.     

EFFECT OF Cu-Ni CONTENT ON THE CORROSION RESISTANCE OF （Cu-Ni）/（10NiO-90NiFe204） CERMET INERT ANODE FOR ALUMINUM ELECTROLYSIS

（Cu-Ni）/（10NiO-90NiFe204） cermet inert anodes containing metal Cu-Ni0, 5, 10, 15 and 20 wt pct were prepared and their corrosion resistance to Na3AlF6-Al2O3 melts was investigated. The results indicate that the content of metal Cu-Ni has little effect on the steady-state concentration of Ni in the electrolyte and the values could not be used to effectively differentiate their corrosion resistance. The steady-state concentration of Fe decreases from 304×10^-6 to 168×10^-6 and that of Cu increases from 21×10^-6 to 71×10^-6 with the content of metal Cu-Ni increasing from 0 to 20 wt pct. Post-examination shows that metallic phase Cu-Ni is corroded preferentially during electrolysis and many pores are left at the anode surface. Considering the corrosion resistance and electrical conductivity, the cermet containing metal Cu-Ni 5 wt pct should be selected and studied further.     

Preliminary testing of NiFe2O4-NiO-Ni cermet as inert anode in Na3AlF6-AlF3 melts

1 Introduction It is well known that the current aluminum reduction cell with carbon consumable anode has many disadvantages. So the concept of inert anode was introduced, with which the disadvantages can be avoided completely. A lot of research work has…     

EFFECT OF Cu-Ni CONTENT ON THE CORROSION RESISTANCE OF (Cu-Ni)/(10NiO-90NiFe2O4) CERMET INERT ANODE FOR ALUMINUM ELECTROLYSIS

(Cu-Ni)/(10NiO-9ONiFe2O4 ) cermet inert anodes containing metal Cu-Ni 0,5, 10, 15 and 20 wt pet were prepared and their corrosion resistance to Na3AlF6-Al2O3 melts was investigated. The results indicate that the content of metal Cu-Ni has little effect on the steady-state concentration of Ni in the electrolyte and the values could not be used to effectively differentiate their corrosion resistance. The steady-state concentration of Fe decreases from 304×10-8 to 168×10-6 and that of Cu increases from 21×10-6 to 71×10-6 with the content of metal Cu-Ni increasing from 0 to 20 wt pct. Post-examination shows that metallic phase Cu-Ni is corroded preferentially during electrolysis and many pores are left at the anode surface. Considering the corrosion resistance and electrical conductivity, the cermet containing metal Cu-Ni 5 wt pct should be selected and studied further.     

烧结气氛对5Ni/(10Ni-NiFe_2O_4)金属陶瓷物相组成及力学性能的影响(英文)

在不同烧结气氛下采用冷压烧结法制备5Ni/(10NiO-NiFe2O4)金属陶瓷,通过XRD研究其物相组成,SEM研究其显微结构,并用三点抗弯测试和抗热震实验检测其力学性能。结果表明:在真空气氛及氧含量分别为2×10-5、2×10-4和2×10-3的气氛中均可获得Ni/(10NiO-NiFe2O4)金属陶瓷,但气氛中氧含量对物相含量影响较大。在真空气氛中NiO含量相对较高。材料中NiFe2O4和Ni的含量分别随着气氛中氧含量的上升而增加和减小;在真空烧结气氛中,可获得晶粒尺寸为3.90μm的5Ni/(10NiO-NiFe2O4)金属陶瓷,其抗弯强度可达138.59MPa,且在960°C实验条件下平均抗热震循环次数可达6.67次,具有相对较好的力学性能。     

NiFe2O4基金属陶瓷惰性阳极的腐蚀研究进展

综述了近年来国内外铝电解用NiFe2O4基金属陶瓷惰性阳极在阳极组元的溶解与分布、腐蚀率的预测与测定以及氧化物和金属相对阳极腐蚀的影响三个方面所做的研究工作。     

镍基惰性阳极的耐腐蚀性研究(下)

探讨Ni0—NiFe204基金属陶瓷惰性阳极在冰晶石——氧化铝熔体中的腐蚀行为，通过实验作出电解质分子比、电流密度及氧化铝浓度与腐蚀速率的关系曲线。针对该镍基惰性阳极，找出了该惰性阳极材料腐蚀速率较小时对应分子比，电流密度及氧化铝浓度等电解过程控制的较佳条件。     

NiFe<Subscript>2</Subscript>O<Subscript>4</Subscript>-based cermet inert anodes for aluminum electrolysis

Recent developments in the preparation, sintering process, mechanical properties, and thermal shock resistance of cermet inert anodes for aluminum electrolysis are reviewed in this paper. To obtain the desired technologies of low-temperature activated sintering of cermet inert anodes, the effects of material composition, sintering atmosphere, sintering temperature, and sintering aids on the densifi cation and microstructure of NiFe₂O₄-10NiO- based ceramics and cermets were studied. To obtain the toughening and strengthening technology of the cermet, the effects of material composition including ceramic and metallic phases are discussed. The cermet inert anodes with high density and mechanical properties were prepared through adjustment of material composition and sintering technology and selection of feasible sintering aids.