硝酸锂

  • 网络lithium nitrate
硝酸锂硝酸锂
  1. LiTi2(PO4)3在硝酸锂水溶液中的电极过程动力学

    Kinetics of Electrode Processes of LiTi_2 ( PO_4 ) _3 in Lithium Nitrate aqueous Solution

  2. 以硝酸锂、硝酸锰为原料,柠檬酸作为络合剂,采用溶胶凝胶法获得前驱体,然后将前驱体在空气气氛中焙烧制备了纳米LiMn2O4。

    Nano-LiMn_2O_4 spinel oxides has been prepared successfully by roasting precursor in the air atmosphere , while precursor was obtained by sol-gel techniques , with lithium nitrate and manganese nitrate as original material and citric acid as complexant .

  3. 吸收式制冷用氨-硝酸锂工质对及循环系统的研究

    The study of Ammonia - Lithium Nitrate Mixtures and absorption refrigeration cycle

  4. 氨&硝酸锂吸收式制冷机性能的计算机模拟研究

    The Simulation of the Lithium-ammonia Nitrate Absorbing and Refrigerating System by Computer Program

  5. 硝酸锂吸收法耗最低,为1078.0kW;

    The least in absorption separation by lithium nitrate ;

  6. 本文采用涂钼热解石墨管,硝酸锂作基体改进剂,石墨炉原子吸收法测定了用新合成路线合成的1-脱氧野尻毒素中钯催化剂残留量。

    A new method for the determination of trace palladium in 1-deoxynojirimycin synthesized by new means .

  7. 建立了涂钼石墨管硝酸锂作基体改进剂测定铍的新方法,提高了灰化温度,降低了原子化温度,增强了抗干扰能力。

    A new method using molybdenum coated graphite tube with lithium nitrate as matrix modifier was established .

  8. 对硝酸锂吸收法分离氨,余热的最小适宜温度为80℃左右,此时消耗的余热量最低;

    The feasible temperature is 80 ℃ in absorption separation by lithium nitrate , and the quantity of heat is least at this temperature ;

  9. 比较了水溴化锂硝酸锂三元工质与传统的水溴化锂工质的单、双效吸收式制冷循环,分析了发生温度、冷凝温度和蒸发温度对系统性能的影响;

    The water-lithium bromide-lithium nitrate absorption refrigeration cycle is compared with the traditional water-lithium bromide system . The effect of generating temperature , condensing temperature and evaporating temperature on system performance is analyzed .

  10. 为克服这种缺陷,提出了一种新的吸收制冷系统,分别以水-溴化锂和氨-硝酸锂作为二个系统的工质,将二系统耦合组成双制冷温度双工质系统。

    A new absorption refrigeration system was presented for overcoming the shortcoming . Two systems respectively with water-lithium bromide and ammonia-lithium nitrate as working pair were coupled in a system with double-chilling temperature and double-working pair .

  11. 研究了原料的配比和焙烧温度对合成材料性能的影响,实验选择硝酸锂、醋酸锰和柠檬酸的摩尔比为1:2:3作为实验的原料配比,500~550℃为配位化合物前驱体的最佳焙烧温度。

    The ratios of primary materials and calcining temperature were studied systematically . The ratios of lithium nitrate , manganese acetate and citric acid are 1:2:3 , and the optimum calcining temperature is 500 ~ 550 ℃ .

  12. 以La3+作为钙的释放剂,以硝酸钾作为锂的消电离剂。

    La ~ ( 3 + ) was as releasing agent for calcium and KNO_3 was served as the deionization agent for lithium .

  13. 研究了其萃取Pr(Ⅲ)的性能,考察了硝酸浓度、萃取剂浓度、硝酸锂浓度以及温度等对萃取分配比的影响。

    The extractive capability for praseodymium (ⅲ) was studied . The effect of concentrations of nitric acid , extractant , LiNO_ ( 3 ) and the temperature on the extraction distribution ratios was investigated in detail .