武汉科技大学 a. 省部共建耐火材料与冶金国家重点实验室, b. 高温材料与炉衬技术国家地方联合工程研究中心,c. 钢铁工业耐火材料新技术国际合作联合实验室,湖北 武汉 430081
覃慧清,夏雨峰,黄青,等. 含锆二氧化硅微粉浆料的流变性[J]. 中国粉体技术,2024,30(6):1-11.
QIN Huiqing, XIA Yufeng, HUANG Qing, et al. Rheological properties of zirconia-containing micro silicas slurries[J]. China Powder Science and Technology,2024,30(6):1−11.
DOI:10.13732/j.issn.1008-5548.2024.06.010
收稿日期:2023-11-09,修回日期:2024-05-22,上线日期:2024-10-18。
基金项目:国家自然科学基金项目,编号:52172023;湖北省科技创新人才计划科技服务人才专项,编号:2023DJC124。
第一作者简介:覃慧清(2000—),女(侗族),硕士生,研究方向为耐火材料。E-mail:qhq20001125@163. com。
通信作者简介:员文杰(1980—),男,教授,博士,博士生导师,研究方向为耐火材料和高温陶瓷复合材料。E-mail:yuanwenjie@wust. edu. cn。
摘要:【目的】 充分发挥含锆二氧化硅微粉浆料在改善浇注料施工性能方面的潜力,探究分散剂对含锆二氧化硅微粉浆料的作用机制及影响因素,旨在为浇注料中含锆二氧化硅微粉原料和分散剂的选用提供依据,优化浇注料的综合性能并降低成本。【方法】 系统研究含锆二氧化硅微粉浆料的特性参数和分散剂对浆料流变性的影响。采用流变仪分别测试含三聚磷酸钠(sodium tripolyphosphate,STPP)、六偏磷酸钠(sodium hexametaphosphate,SHMP)、 FS20型聚羧酸盐分散剂的质量分数分别为 0. 2%、0. 2%、0. 1%的含锆二氧化硅微粉浆料的流变性能;利用灰色关联度分析方法,研究了含锆二氧化硅微粉特性与浆料流变参数的关联性;结合 Herschel-Bulkey模型,探究了分散剂对含锆二氧化硅微粉浆料流变性的影响。【结果】 在剪切速率为0. 13 s-1 的情况下,浆料的pH和含锆二氧化硅微粉的D50与含锆二氧化硅微粉浆料流变性的关联度分别是0. 975 3、0. 942 7;添加3种分散剂后,浆料均呈现剪切变稀的特性,表明所选的3种分散剂对含锆二氧化硅微粉浆料的流变性有改善效果。【结论】 浆料的流变性受浆料pH、含锆二氧化硅微粉的D50粒径及微粉粒径分布和表面羟基含量的共同影响,这些因素不仅决定了浆料的基本流变特性,而且对分散剂的效能发挥起着重要作用。添加离子型表面活性分散剂STPP、SHMP相对于FS20型聚羧酸盐分散剂更有助于降低含锆二氧化硅微粉浆料的黏度。粒径分布范围较宽和表面羟基更多的含锆二氧化硅微粉在STPP作用下浆料的分散效果最好; pH略大的含锆二氧化硅微粉因对磷酸根的吸附受到抑制,则需要添加SHMP才能获得黏度最小的浆料。
关键词:含锆二氧化硅微粉;分散剂;流变性;灰色关联度分析; Herschel-Bulkey 模型
Objective Owning to their advantages, including easy production, simple construction, no need for firing, and fewer joints that can lead to lower corrosion, monolithic refractories such as castable have replaced traditional shaped refractories in most application fields. The use of a large amount of micro powders makes the dispersion of castable crucial for construction. Zirconia-containing micro silicas, a by-product of the desilication process in zirconium production, boasts enhanced dispersibility and favorable rheological properties. These characteristics can reduce the required amount of dispersant, lower construction costs,and exhibit promising application potential. To fully utilize its potential to improve the construction and service performance of castable, the rheological properties of zirconia-containing micro silicas slurries were systematically investigated. The effects of powder characteristics and dispersant on their rheological properties were analyzed. The results can provide practical guidance for the development and utilization of castable with zirconia-containing micro silicas.
Methods In this paper, three grade zirconia-containing micro silicas powders (SIF-A, B, C) produced by Imerys Fused Minerals Yingkou Co. , Ltd. were selected. The phase of zirconia in micro silicas was identified by X-ray diffraction (XRD). The microstructure of zirconia-containing micro silicas was observed using transmission electron microscopy (TEM). Functional groups of zirconia in micro silicas were identified by Fourier transform infrared spectroscopy (FTIR). The particle size distribution of micro silicas was tested by a laser particle size analyzer. A 5% mass fraction slurry was prepared and the Zeta potential of the solution was measured at different pH values. The rheology of zirconia-containing micro silicas micro powders slurries containing 0. 2% sodium tripolyphosphate (STPP),0. 2% sodium hexametaphosphate (SHMP), and 0. 1% FS20-type polycarboxylate dispersant in mass fractions was measured using a cylindrical coaxial rotational rheometer. The shear stress-shear rate relationship of zirconia-containing micro silicas slurries with different dispersants was fitted using the Herschel-Bulkey model. Rheological parameters were investigated using gray correlation analysis combined with weighting analysis.
Results and Discussion Tetragonal zirconia in micro silicas was detected by XRD. It was observed that large spherical particles contained numerous smaller zirconia particles. The median particle size D50 of micro silicas A and the grading accuracy D75/D25 were the largest. All three saturated solutions of zirconia-containing micro silicas were strongly acidic, with pH values in the order A<B<C due to the high content of soluble acidic oxide P2O5 in micro silicas. The absolute value of the Zeta potential of the slurries increased with the increase of pH in the acidic environment. According to the grey correlation analysis, the correlation between the pH of the slurry and the D50 of the powders, and the rheological properties of the zirconia-containing micro silicas slurries at a shear rate of 0. 13 s-1 were 0. 975 3 and 0. 9427, respectively, consistent with the calculated values of the weighting. There was a positive correlation between the particle size of zirconia-containing micro silicas and the rheological properties of its slurries. With the addition of different dispersants, the zirconia-containing micro silicas slurries exhibited shear thinning characteristics. The addition of sodium tripolyphosphate (STPP) and sodium hexametaphosphate (SHMP) dispersants brought the zirconia-containing micro silicas slurry close to Newtonian fluid. The improvement of slurry rheology by STPP and SHMP was greater than that of the polycarboxylate FS20. For micro silicas A, the dispersion effect of STPP was the highest. The most effective dispersant was SHMP for micro silicas B and C. This was because the hydroxyl groups on the surface of the zirconia-containing micro silicas interacted more effectively with water molecules under the action of proper amount of phosphate. The phosphate content of STPP was lower than that of SHMP. For micro silicas A with more surface hydroxyls, STPP was the best dispersant, whereas for samples B and C containing fewer surface hydroxyls, SHMP provided more phosphate for better dispersion. In addition, an increase in pH inhibited the adsorption of phosphate. Therefore, the phosphate dispersant was more significant for micro silicas A.
Conclusion The zirconia particles are located on the surface of silica or encapsulated in larger silica particles. The saturated solutions of three selected zirconia-containing micro silicas for this study all exhibit strong acidity, with pH values A<B<C. In acidic environment, the absolute value of the Zeta potential of the slurry increases with the increase of pH value. The influence of the characteristics of zirconia-containing micro silicas on its rheological properties was analyzed using the grey correlation analysis method. The pH value of the slurry and the D50 particle size have the greatest impact on its rheological properties. For larger micro silicas particles and lower pH values of the slurry, the rheological properties are better. Zirconia-containing micro silicas slurries with different dispersants exhibit shear thinning characteristics. The slurries are approximately Newtonian fluid when STPP and SHMP were added as dispersants. The effects of STPP and SHMP on their rheological properties are more significant than those of polycarboxylate superplasticizers. At a certain shear rate, weak intermolecular forces between particles in the slurry are disrupted, weakening the adsorption of polymer structures. Therefore, under shear force, the dispersion effect of ionic surfactants is stronger than that of polycarboxylate dispersants. Zirconia-containing micro silicas with a larger range of particle size distribution and more surface hydroxyl groups shows the best dispersion with STPP. Zirconia-containing micro silicas with slightly higher pH values requires the addition of SHMP to obtain slurries with minimized viscosity, as their adsorption of phosphate is inhibited.
Keywords:zirconia-containing micro silica; dispersant; rheological property; grey correlation analysis; Herschel-Bulkey model
[1]SARKAR R. Binders for refractory castables: an overview[J]. Interceram International Ceramic Review,2020,69(4):44-53.
[2]BEZERRA B P, LUZ A P, PANDOLFELLI V C. Novel drying additives and their evaluation for self-flowing refractory castables[J]. Ceramics International,2020,46(3):3209-3217.
[3]HABIB A O, AIAD I, EL-HOSINY F I, et al. Development of the fire resistance and mechanical characteristics of silica fume-blended cement pastes using some chemical admixtures[J]. Construction and Building Materials,2018,181:163-174.
[4]SENFF L, HOTZA D, REPETTE W L, et al. Rheological characterisation of cement pastes with nano silica, silica fume and superplasticiser additions[J]. Advances in Applied Ceramics,2010,109(4):213-218.
[5]LIANG Y, ZHANG H, DING H, et al. Amorphous silica: prepared by byproduct micro silica in the ferrosilicon production and applied in amorphous silica-TiO2 composite with favorable pigment properties[J]. Journal of Materials Research and Technology,2023,26:235-245.
[6]王超,石颖恒,瞿玲,等. 分散剂对含锆二氧化硅微粉浆料流变性的影响[J]. 陶瓷学报,2020,41(5):678-685.
WANG C, SHI Y H, QU L, et al. Effects of dispersants on rheological properties of silica fume slurries[J]. Journal of Ceramics,2020,41(5):678-685.
[7]JIANG Q, XIE Y L, JING L Q, et al. Low-temperature sintering of a porous SiC ceramic filter using water glass and zirconia as sintering aids[J]. Ceramics International,2021,47(18):26125-26133.
[8]LI J G, CAI Q W, LUO G Q, et al. Zirconia toughened alumina ceramics via forming intragranular structure[J]. Materials,2024,17(6):1309.
[9]CHEN Y G, TAN J L, SUN J X, et al. Effect of sintering temperature on the microstructures and mechanical properties of ZrO2 ceramics fabricated by additive manufacturing[J]. Ceramics International,2024,50(7):11392-11399.
[10]JIN E D, ZOU C, DING D H, et al. Enhanced mechanical properties and thermal shock resistance of magnesia refractories via in situ formation of tetragonal zirconia[J]. Ceramics International,2024,50(9):14968-14979.
[11]ZADOROZHNAYA O Y, KHABAS T A, TIUNOVA O V, et al. Effect of grain size and amount of zirconia on the physical and mechanical properties and the wear resistance of zirconia-toughened alumina[J]. Ceramics International,2020,46(7):9263-9270.
[12]GUN’KO V M, BORYSENKO M V, PISSIS P, et al. Polydimethylsiloxane at the interfaces of fumed silica and zirconia/fumed silica[J]. Applied Surface Science,2007,253(17):7143-7156.
[13]BURROUGHS J F, WEISS J, HADDOCK J E. Influence of high volumes of silica fume on the rheological behavior of oil well cement pastes[J]. Construction and Building Materials,2019,203:401-407.
[14]OTROJ S, NILFORUSHAN M R, DAGHIGHI A, et al. Impact of dispersants on the mechanical strength development of alumina-spinel self-flowing refractory castables[J]. Ceramics Silikáty,2010,54(3):284-289.
[15]WANG Y, ZHU B, LI X, et al. Effect of dispersants on the hydrate morphologies of spinel-containing calcium aluminate cement and on the properties of refractory castables[J]. Ceramics International,2016,42(1):711-720.
[16]WANG T T, BAI Q S, GUO W M, et al. Effects of fused silica surface roughness on the interfacial adsorption mechanism of contaminant[J]. Journal of Materials Science,2023,58(36):14284-14298.
[17]武玉洁,沙淑莉,董妍,等. 二氧化硅二维漫反射红外光谱特征研究[J]. 有机硅材料,2019,33(6):479-487.
WU Y J, SHA S L, DONG Y, et al. Study on characteristics of two-dimensional diffuse reflectance infrared spectrum of silicon dioxide[J]. Silicone Material,2019,33(6):479-487.
[18]KOBASHI T, CHAI Y D, YAMAD I. et al. Effective control of water-interactive states on mesoporous silica films by phosphoric acid addition[J]. Materials Chemistry and Physics,2019,227:134-137.
[19]WANG W J, ZHOU J, WEI D, et al. ZrO2-functionalized magnetic mesoporous SiO2 as effective phosphate adsorbent[J]. Journal of Colloid and Interface Science,2013,407:442-449.
