黑液燃烧法绿液除硅绿液硅不溶物的形貌组成及其性能研究

采用偏铝酸钠和硫酸镁复配除硅剂进行竹浆黑液燃烧法绿液除硅研究,获得绿液硅不溶物,采用ICP及SEM-EDAX确定组成,采用SEM观察形貌,采用激光粒度仪以及沉降法测定绿液硅不溶物粒径分布、沉降体积和时间评价绿液硅不溶物的沉降性能.研究表明,偏铝酸钠和硫酸镁复配除硅剂具有较好的除硅效果,除硅剂摩尔比Si∶Al∶Mg为1∶0.3∶0.4时,除硅率最高可达86.17%,绿液硅不溶物的球形块状结构最明显,絮聚最明显,同时伴随着表面吸附着更细小的绿液硅不溶物颗粒;除硅剂摩尔比Si∶Al∶Mg为1∶0.35∶0.35,绿液中Al、Mg元素含量最低,除硅率为85.84%,相应的绿液硅不溶物的平均粒径最大,为39μm,粒径主要集中在3~70μm,沉降性能也较好;除硅剂摩尔比Si∶Al∶Mg为1∶0.3∶0.4和1∶0.35∶0.35的绿液硅不溶物Si元素含量最高,为5.82%,后者绿液硅不溶物Al、Mg元素含量高于前者,最终确定除硅剂配比工艺Si∶Al∶Mg为1∶0.35∶0.35.

硫酸盐竹浆黑液流变特性及燃烧法除硅的研究

研究了中高浓硫酸盐竹浆黑液的流变特性以及铝盐燃烧法除硅效果。研究表明,竹浆黑液在0.1~100 s^(-1)的剪切速率范围内近似于非牛顿流体,并且随着剪切速率的改变产生剪切-稀化现象。高固形物含量的竹浆黑液在一定的剪切速率范围内符合幂律区特征。在黑液燃烧法除硅中,铝盐除硅剂用量为2.5%(对固形物含量)时,黑液沉淀物中硅含量为20.15%,具有较好的除硅效果。

碱回收绿液除硅及应用的研究

研究了二氧化碳(CO_2)法绿液除硅工艺以及除硅后的白泥应用效果。结果表明,将绿液澄清,控制总悬浮物(TSS)为60 mg/L以下,CO_2法绿液除硅的优化工艺条件为:CO_2气体流量0. 5～1 L/min,反应温度70～90℃,pH值控制在9. 8～10. 2,硫酸铝加入量1. 5 g/L。在优化工艺条件下,绿液硅含量从CO_2处理前的2. 98%降至处理后的0. 12%,除硅率可达96%。绿液钠含量(总碱)从除硅前的4. 70%降至除硅后的4. 56%,说明在保证绿液中主要成分钠含量基本不变的情况下,达到了很好的除硅效果。CO_2绿液除硅工艺简单,除硅率高,苛化后的白泥基本不含硅,产生的白泥容易洗涤,残碱量低,提高了白泥的品质。除硅后制得的白泥碳酸钙加填纸的施胶性能、强度指标等与商品PCC (沉淀碳酸钙)加填纸很接近,完全可以替代商品PCC用于纸张加填。

黑液浓缩新技术研究进展

讨论了黑液浓缩的新技术和新方法,包括热解降低粘度法、膜分离法、除硅法和结冰浓缩法四种。热解降低粘度法和除硅法处理黑液可以得到高浓度黑液,而膜分离法和结冰浓缩法可用来预浓缩黑液并且成本较低。

Thermodynamic analysis on reaction behaviors of silicates in (NH_4)_2WO_4-(NH_4)_2CO_3-NH_3-H_2O system

The reaction behaviors of silicate species in （NH4）2WO4-（NH4）2CO3-NH3-H2O system are crucial to developing a greenmanufacture technique for ammonium paratungstate. In order to efficiently remove silicon from the system, the reaction behaviors ofsilicate species were systematically investigated by thermodynamic analysis. The thermodynamic analysis shows that silicate in thetungstate clinker partly decomposes in the leaching process, with 150-160 mg/L silicon thermodynamically at 25 ℃. The dissolvedsilicon can be removed by magnesium salts via forming insoluble MgSiO3. The low carbonate and high ammonia concentrations inthe system are beneficial to the removal of silicon, with silicon concentration reaching 8-10 mg/L thermodynamically, whereasMgSiO3 precipitation is hardly formed when the concentration of total carbonate is more than 1.5 mol/L. The reaction behaviors ofcalcium and magnesium were also studied in the system. The results in the verification experiments consist with the theoreticalcalculation.