莫来石含量对堇青石-莫来石复相陶瓷性能的影响

以合成堇青石(≤0.074 mm)和合成莫来石(0.45～0.9 mm)为主要原料,a-Al2O3微粉(≤0.044 mm)、镁砂(≤0.054 mm)和熔融石英(≤0.054 mm)为添加剂,经细磨、造粒、成型后,于1 370℃4 h烧成后制备了莫来石质量分数分别为15%、20%、25%、30%、35%和40%的堇青石-莫来石复相陶瓷材料,研究了莫来石含量对复相陶瓷材料烧结性能、抗折强度、热膨胀性及抗热震性的影响.结果表明:随着莫来石含量的增加,堇青石一莫来石复相陶瓷材料的体积密度、显气孔率和热膨胀系数都呈上升趋势,而抗折强度呈降低趋势;适当提高莫来石含量有利于复相陶瓷材料的抗热震性,当莫来石含量达到30%时,材料的抗热震性最好.     

原位反应烧成莫来石-堇青石复合材料及其特性(英文)

通过原位反应烧成方法制备了不同莫来石、堇青石含量比的复合材料。首先,根据堇青石和莫来石的理论化学组成,分别将高岭土、工业氧化铝和滑石混合,配制出堇青石生料粉(C粉)和莫来石生料粉(M粉)。然后,再将C粉和M粉按不同的设计比例混合,烧结制备出一系列莫来石-堇青石复合材料。添加V2O5添加剂,考察其对烧结复合材料的影响。并通过X射线衍射,微观结构观察,热力学性质检验,比较了不同莫来石、堇青石含量比的复合材料的特性。制备的莫来石-堇青石复合材料所用的烧结温度可降低至1380℃,且复合材料中堇青石和莫来石晶体发育良好,复合材料抗热震性好。     

堇青石-莫来石质匣钵材料抗热震性和抗侵蚀性研究

堇青石-莫来石质耐火材料具有热膨胀系数低、容重轻、吸热少、体积稳定性好和抗热震性好等特性.以堇青石、莫来石为主要原料,加入一定量的电熔氧化镁、活性氧化铝和硅微粉等微粉为辅助原料,制备了堇青石-莫来石质匣钵材料.研究了颗粒级配和烧成温度对堇青石-莫来石质匣钵材料物相组成和显微结构的影响,并对材料的热震性和侵蚀性进行评估.结果表明:烧成温度在1300～1400℃,对热震后的三组试样进行性能检测,发现配方一试样具有好的抗热震性和抗侵蚀性,其残余抗折强度在3.0～4.5 MPa之间,残余耐压强度在17.5～24.5 MPa之间.     

原位莫来石-堇青石复合物的物理机械性能、耐火性能和显微结构

原位莫来石-堇青石复合物是由高岭石、滑石和氧化铝,在堇青石含量为5%￣35%范围内,于1300℃、1400℃和1500℃烧成并保温3h制成。XRD和SEM结果显示莫来石-堇青石复合物在1400℃完全形成。在1500℃所有堇青石转变为莫来石和玻璃相,导致突然致密,在堇青石为20%时达最佳致密。25%￣35%堇青石试样不能显示良好致密,尽管从堇青石分解中形成了大量熔融物。然而由于莫来石颗粒分布均匀和压实的显微结构,在这些试样中可以获得最高的常温耐压强度。在所有烧成温度下所有试样都显示了抗热震性好,而在1500℃烧成的试样显示由于形成了高耐火莫来石相,故荷重软化温度最高。     

黏土的杂质含量对堇青石-莫来石复合材料相组成及性能的影响

以滑石细粉、高铝矾土细粉和两种不同杂质含量的黏土细粉为原料,经配料、加水混练成型后,分别于1300、1350和1400℃保温3h制备了堇青石-莫来石复合材料的试样,用XRD、SEM等研究了黏土中杂质含量对堇青石-莫来石复合材料相组成及性能的影响。结果表明:1)使用高杂质含量的黏土能有效降低试样的烧结温度,促进堇青石和莫来石晶体的生成发育,提高试样的体积密度与常温抗折强度,但对其抗热震性损害较大。2)使用高杂质含量的黏土时,提高MgO含量虽然可增加堇青石的含量,但玻璃相含量增加且黏度降低,不能有效提高材料的抗热震性;而使用低杂质含量的黏土时,通过控制引入MgO的含量与煅烧温度,可调节试样中晶相的含量与组成,从而可提高材料的抗热震性。     

堇青石—莫来石棚板抗热震性能的研究

采用莫来石为骨料,堇青石为基料制作堇青石—莫来石棚板,研究莫来石与堇青石配比、骨料种类、烧成温度等因素对材料抗热震性能的影响。     

高温气体过滤器支撑体的抗热震性能改进研究

为了改善高温气体过滤器支撑体的强度及抗热震性能,根据复合材料韧化强化原理,本试验采用陶瓷材料复合技术,制备莫来石-刚玉-钛酸铝-堇青石复合陶瓷材料,探索其作为高温过滤器支撑体的可能性.以粒径小于74μm的高铝矾土熟料、钛酸铝、堇青石为原料,以聚乙烯醇的溶液(质量浓度2％)为结合剂,试样成型压力为50MPa,烧结温度为1360℃,保温3小时制备了莫来石-刚玉-钛酸铝-堇青石复合材料.对烧后试样进行体积密度、气孔率、常温抗折强度、抗热震性的测定及XRD、SEM的分析,研究了配料组成对复合材料烧结及抗热震性能的影响.研究结果表明:具有较好烧结性能与抗热震性能的莫来石-刚玉-钛酸铝-堇青石复合材料支撑体的最佳物料配比(％)为:高铝矾土熟料30％、钛酸铝10％、堇青石60％.     

红柱石基刚玉-莫来石复相陶瓷的显微结构及性能

以红柱石颗粒为主要骨料,辅以莫来石颗粒和刚玉颗粒,硅微粉、铝微粉为基质料,经混合、困料及成型后,经不同温度下烧成4h,制得莫来石基刚玉-莫来石复相陶瓷,分析了烧成温度对复相陶瓷的物相组成、显微结构、烧成性能、力学性能及热学性能。结果表明:红柱石在高温下转化成针状和柱状莫来石改善复相陶瓷的烧成性能和抗热震性能;在1480℃烧成时,红柱石刚玉-莫来石复相陶瓷具有优越性能,其抗折强度为15.4MPa,耐压强度为91.6MPa,热膨胀系数为5.5×10-6/K,1100℃下水冷的抗热震次数达到99次。     

烧成工艺对堇青石-莫来石窑具材料性能的影响

以堇青石、莫来石、高岭土和氧化铝微粉为原料制备堇青石-莫来石窑具材料,研究了烧成温度、保温时间对堇青石-莫来石窑具材料的常温性能、高温抗折强度和抗热震性的影响。并通过XRD分析了试样烧成后的物相变化,通过SEM观察了试样的显微结构。结果表明:随烧成温度从1340℃提高到1400℃,试样的线膨胀率增加,显气孔率增加,常温抗折、常温耐压强度和高温抗折强度增大,但1370℃烧成后的试样的抗热震性最好;对1370℃烧成的试样,随保温时间从3 h延长到5 h,试样的常温性能、高温抗折强度及抗热震性都有所降低。综合分析,在1370℃下保温3 h烧成的试样性能较为优良。     

凝胶注模堇青石-莫来石复相材料的制备及其抗热震性能

采用凝胶注模方法制备堇青石-莫来石复相材料,研究了聚乙烯醇对浆料稳定性、固化时间和表面氧阻聚的影响,分析了堇青石-莫来石复相材料的抗热震性能。结果表明,聚乙烯醇可提高粗颗粒悬浮体系的稳定性,增大浆料黏度,延长固化时间。聚乙烯醇还可以起到消除表面起皮、开裂的作用。通过控制浆料固相含量调节堇青石-莫来石复相材料的气孔分布,从而影响其热震稳定性。当浆料中堇青石-莫来石固相体积分数为41%～44%时,堇青石-莫来石复相材料的热震稳定性最好。     

In situ synthesis and thermal shock resistance of a cordierite-mullite composite for solar thermal storage

Cordierite-mullite composite ceramic was synthesized in situ by semidry pressing and pressureless sintering from andalusite, kaolin, γ-Al₂O₃, talc, potassium feldspar, and albite in air. The effects of composition and sintering temperature on the density, bending strength, thermal shock stability, crystal phases, and microstructure of the specimens were studied. The results show that specimen B2 (the theoretical content of cordierite was 20 wt%) has excellent performance, that is, a bending strength of 104.59 MPa, 30 cycles of thermal shock resistance without cracking, and a loss rate of 13.12%. X-ray diffractometer (XRD) analysis and scanning electron microscope (SEM) micrographs showed that spherical cordierite crystals were grown on the surface of the mullite, therefore, the specimen possessed a superior bending strength and thermal shock resistance, where a great number of granules combined to restrain crack initiation as well as propagation over time during the thermal shock test. The thermal conductivity of specimen B2 was determined to be 3.83 W/(m·K) (36°C), and the sensible heat storage density was 1136 kJ/kg, with the temperature difference (ΔT) ranging from 0 to 800°C. Consequently, the cordierite-mullite composite is a potentially applicable material for solar thermal storage.     

Preparation and thermal shock resistance of corundum-mullite composite ceramics from andalusite

Corundum-mullite composite ceramics have high hardness, small plastic deformation and other excellent performances at high temperature. Corundum-mullite composite ceramics were fabricated from andalusite and α-Al₂O₃ by in-situ synthesis technology. Effects of mullite/corundum ratio and sintering temperatures on the water absorption, apparent porosity, bulk density, bending strength, thermal shock resistance, phase composition and microstructure of the sample were investigated. Results indicated that the in-situ synthesized mullite from andalusite combined with corundum satisfactorily, which significantly improved the thermal shock resistance as no crack formed after 30 cycles of thermal shock (1100 °C-room temperature, air cooling). Formula A4 (andalusite: 37.31 wt%, α-Al₂O₃: 62.69 wt%, TiO₂ in addition: 1 wt%, mullite: corundum=6:4 in wt%) achieved the optimum properties when sintering at 1650 °C, which were listed as follows: water absorption of 0.15%, apparent porosity of 0.42%, and bulk density of 3.21 g⋅cm⁻³, bending strength of 117.32 MPa. The phase composition of the sintered samples before and after thermal shock tests were mullite and corundum constantly. The fracture modes of the crystals were transgranular and intergranular fractures, which could endow the samples with high thermal shock resistance.     

Effect of the calcined andalusite aggregates on the micro-crack formation and thermal shock resistance of mullite castables

The effect of calcined andalusite aggregates on the micro-crack formation and thermal shock resistance of mullite castables was investigated and analyzed. The mullite castables were prepared from andalusite aggregates calcined at high temperatures. The results show that the micro-cracks from the transformation of andalusite to mullite can effectively relieve thermal stress, improving the thermal shock resistance of mullite castables. The micro-cracks generated decreased with increasing calcine temperatures of the andalusite aggregates. When the calcine temperature was increased from 1300 °C to 1500 °C, the thermal shock resistance of mullite castables was found to continuously increase. However, the thermal shock resistance of mullite castables with the andalusite aggregates calcined at 1600 °C is lower than those with the andalusite aggregates calcined at 1500 °C.     

Preparation and performance study of cordierite/mullite composite ceramics for solar thermal energy storage

The employment of solar energy in recent years has reached a remarkable edge. It has become even more popular as the cost of fossil fuel continues to rise. Energy storage system improves an adjustability and marketability of solar thermal and allowing it to produce electricity in demand. This study attempted to prepare cordierite/mullite composite ceramics used as solar thermal storage material from calcined bauxite, talcum, soda feldspar, potassium feldspar, quartz, and mullite. The thermal physical performances were evaluated and characterized by XRD, SEM, EPMA, and EDS. It was found that the optimum sintering temperature was 1280°C for preparing, and the corresponding water adsorption was 11.25%, apparent porosity was 23.59%, bulk density was 2.10 mg·cm^?3, bending strength was 88.52 MPa. The residual bending strength of specimen sintered at 1280°C after thermal shock of 30 times decreased to be 57 MPa that was 36% lower than that before. The thermal conductivity of samples sintered at 1280°C was tested to be 2.20 W·(m·K)^?1 (26°C), and after wrapped a PCM (phase change materials) of K₂SO₄, the thermal storage density was 933 kJ·kg^?1 with the temperature difference (ΔT) ranged in 0‐800°C. The prepared cordierite/mullite composite ceramic was proved to be a promising material for solar thermal energy storage.     

Effects of SiC content on thermal shock behavior and elastic modulus of cordierite–mullite composites

Cordierite (Mg₂Al₄Si₅O₁₈) is a commercially available ceramic with low fracture toughness that hampers its broad industrial applications. Although several studies have reported the mechanical improvement of cordierite using various reinforcements, modulating its mechanical and thermal shock characteristics is not explored precisely. In the present research, we investigated the manufacturing of cordierite–mullite ceramics and the role of SiC on their thermomechanical properties. The in-situ formed mullite particles were obtained by mixing andalusite-talc-alumina and addition of SiC. It was found that thermal shock behavior and elastic moduli are dependent on SiC content and retained porosity. Furthermore, the addition of SiC to cordierite-based ceramics could enhance the thermal shock resistance via proper activation of the crack bridging mechanism in the matrix of the prepared composite.     

蜂窝陶瓷蓄热材料的研究现状

蜂窝陶瓷蓄热材料应该具有热膨胀系数低、比热容大、比表面积大、导热性能好、抗热震性好等特性。本文详细介绍了几种多孔陶瓷材料的优缺点,指出堇青石质复相材料是目前研究最广泛的蜂窝陶瓷材料。堇青石与多种催化剂匹配性好,比表面积大、热膨胀系数小,但耐热性稍差,于是通过添加一些添加剂来提高堇青石作为蜂窝陶瓷蓄热体的性能。这些添加剂与堇青石结合形成复相材料,可以降低热膨胀系数、提高抗热震性等。     

刚玉–莫来石–镁铝尖晶石复合陶瓷的原位合成及热震行为

以α-Al2O3、苏州土、滑石和石英为主要原料,采用无压烧结制备了刚玉–莫来石–镁铝尖晶石多相复合陶瓷,研究了烧结温度对样品的体积密度、线性收缩率和吸水率等烧结性能以及机械性能的影响。通过X射线衍射和扫描电子显微镜分析了复相陶瓷热震前后的物相组成和显微结构。结果发现：经1480℃烧结的样品吸水率为0.19%,体积密度为3.06g/cm3,抗折强度达99.59MPa,复合材料有较好的热震性能,1100℃空冷热震损失率仅6.9%,可耐受17次热冲击。该复相陶瓷可作为潜在的太阳能热发电材料。     

水泥窑用特种硅莫砖的研制及应用

以高铝矾土熟料、90碳化硅、棕刚玉为主要原料,添加红柱石粉、广西白泥等外加剂,通过合理的颗粒级配,采用高压成型、高温烧成等方法,制备出水泥窑用特种硅莫砖,并研究了烧成后试样的体积密度、气孔率、强度、微观结构和耐磨性.结果表明:添加6％红柱石粉在1420℃制备的硅莫砖的性能最优,其体积密度为2.74 g/cm3,抗热震性30次,磨损量为1.06 cm3,热导率为1.65 W/(m·K),耐压强度高达159 MPa,在5000 t/d水泥回转窑过渡带上使用该产品,寿命可达一年以上,这是由于窑简体外表面温度比使用镁尖晶石砖平均降低80℃以上,极为有效地延长了该砖衬的使用寿命.