北京科技大学学报
北京科技大學學報
북경과기대학학보
JOURNAL OF UNIVERSITY OF SCIENCE AND TECHNOLOGY BEIJING
2013年
3期
347-351
,共5页
氧化钙%硫酸钙%固相反应%球磨
氧化鈣%硫痠鈣%固相反應%毬磨
양화개%류산개%고상반응%구마
malcium oxide%calcium sulfate%solid state reaction%ball milling
以锰尾矿制备硫酸锰过程中副产硫酸钙为原料在室温下与碳酸氢铵进行固相球磨反应,制备出氧化钙的前驱体碳酸钙,然后将其煅烧得到氧化钙.分别考察了物料配比、球磨时间、球料质量比等因素对硫酸钙转化率的影响,采用 X 射线衍射和化学分析方法对产物进行了分析,并对室温固相球磨反应的机理进行了探讨.在物料配比(摩尔比)为3.5:1、球磨时间为40 min 以及球料质量比为5:1时,硫酸钙的转化率可达到99.8%,将固相产物在1000℃热解1 h 后所制备的氧化钙纯度为99.2%.室温球磨过程细化了反应物的颗粒尺寸,增加了反应物的接触面积,为引发反应提供了必要的能量,因此提高了化学反应的有效性.
以錳尾礦製備硫痠錳過程中副產硫痠鈣為原料在室溫下與碳痠氫銨進行固相毬磨反應,製備齣氧化鈣的前驅體碳痠鈣,然後將其煅燒得到氧化鈣.分彆攷察瞭物料配比、毬磨時間、毬料質量比等因素對硫痠鈣轉化率的影響,採用 X 射線衍射和化學分析方法對產物進行瞭分析,併對室溫固相毬磨反應的機理進行瞭探討.在物料配比(摩爾比)為3.5:1、毬磨時間為40 min 以及毬料質量比為5:1時,硫痠鈣的轉化率可達到99.8%,將固相產物在1000℃熱解1 h 後所製備的氧化鈣純度為99.2%.室溫毬磨過程細化瞭反應物的顆粒呎吋,增加瞭反應物的接觸麵積,為引髮反應提供瞭必要的能量,因此提高瞭化學反應的有效性.
이맹미광제비류산맹과정중부산류산개위원료재실온하여탄산경안진행고상구마반응,제비출양화개적전구체탄산개,연후장기단소득도양화개.분별고찰료물료배비、구마시간、구료질량비등인소대류산개전화솔적영향,채용 X 사선연사화화학분석방법대산물진행료분석,병대실온고상구마반응적궤리진행료탐토.재물료배비(마이비)위3.5:1、구마시간위40 min 이급구료질량비위5:1시,류산개적전화솔가체도99.8%,장고상산물재1000℃열해1 h 후소제비적양화개순도위99.2%.실온구마과정세화료반응물적과립척촌,증가료반응물적접촉면적,위인발반응제공료필요적능량,인차제고료화학반응적유효성.
@@@@Calcium oxide (CaO) was prepared by directly pyrolyzing the precursor called calcium carbonate (CaCO3), which was synthesized by solid-state ball milling reaction between NH4HCO3 and CaSO4·2H2O, the by-product generated during the preparation of MnSO4. The effects of NH4HCO3-to-CaSO4·2H2O molar ratio, milling time, and ball-to-feed mass ratio on the conversion of CaSO4·2H2O were investigated respectively. The product was analyzed by X-ray diffraction and chemical analytical method. The reaction mechanism was also discussed. When the NH4HCO3-to-CaSO4·2H2O molar ratio is 3.5:1, the milling time is 40 min, and the ball-to-feed mass ratio is 5:1, the conversion rate of CaSO4·2H2O reaches 99.8%. Calcium oxide, whose purity is 99.2%, can be prepared by pyrolyzing the precursor at 1000 ℃ for 1 h. The effectiveness of the solid-state reaction is improved by refining the reactant size, increasing the contact area, and providing necessary energy during the ball-milling process at ambient temperature.
