1) cell voltage
槽电压
1.
Factors influencing the cell voltage of electrolyzers of 30DD350 type;
30DD350型电解槽电压的影响因素
2.
The causes of cell voltage increase in ion-exchange membrane caustic soda plants;
离子膜烧碱装置槽电压上升原因
3.
Influential factors and reducing measures of electrolyzer cell voltage;
影响槽电压的因素及降低措施
2) tank voltage
槽电压
1.
Determination of the relationship between current density and tank voltage in electrocoagulation process;
电絮凝过程电流密度与槽电压关系研究
2.
The treatment of industrial wastewater containing phosphorus using bulk electrolysis was investigated by synthetic boron-doped diamond(BDD) thin film electrodes to explore the influences of the time,tank voltage and the distance of electrodes on the rate of the degradation.
用掺硼金刚石(BDD)作电极,采用循环电解法处理含磷工业废水,研究了电解时间、槽电压及电极间距对有化学需氧量(COD)降解率的影响。
3.
The treatment of petroleum wastewater using bulk electrolysis was investigated by synthetic boron-doped diamond(BDD) thin film electrodes to explore the influences of the time,tank voltage and the distance of electrodes on the rate of the degradation.
用BDD(掺硼金刚石)作电极,采用循环电解法处理石油污水,研究了电解时间、槽电压及电极间距对有COD(化学需氧量)降解率的影响,实验发现在槽电压8 V、电极间距2 mm,经过5h电解废水的COD降解率达到了93。
3) voltage
[英]['vəʊltɪdʒ] [美]['voltɪdʒ]
槽电压
1.
Effects on electrolyzer voltage and current efficiency were discussed.
初步探讨了它们对槽电压和电流效率的影响,介绍了处理方法和效果。
2.
The relationship between the half-dyeing time of electrochemical dyeing of the fabric and the voltage of dye box and temperature is studied from the viewpoint of dynamics.
从动力学角度出发研究了织物电化学染色半染时间与槽电压和温度的关系。
3.
The inner structure of perfluorinated ionic membrane,the formation of impurity and mass transfer of ionic cluster in ionic membrane and its influence on current efficiency and voltage were introduced.
介绍了全氟离子膜的内部结构、离子膜中离子簇传质过程及杂质的形成及其对离子膜电流效率和槽电压的影响。
4) bath voltage
槽电压
1.
The article is analyze to analyze four parts of diaphragmatic electrobath voltage and the various factors of every parts as well as controlling those factors to decrease the diaphragmatic electrobath voltage, and gives account of general situation and development of this aspect which is good references for the technician to study, design and operate the diaphragmatic electrobath voltage.
从降低电解槽槽电压的角度 ,对槽电压组成的四个部分以及每一部分的各种因素进行了详细的分析 ,并讨论了如何控制这些因素来降低槽电压 ,同时介绍了这方面的现状和进展。
2.
Taking DELL 486 computer as management computer,taking SYSMAC C1000H programmable controller as control computer,according to the mathematical model corrected by bath resistance adding current waving,to automatically regulate the pole distance,control bath voltage,thus the production can be stabilized,the current efficiency can be increased,power can be saved of 323kW·h/t·A
用DELL486 微机作管理机,用SYSM AC C1000H 可编程序控制器作控制机,根据槽电阻加电流波动校正的数学模型,自动调整极距,控制槽电压,稳定生产,提高了电流效率,节电323kW ·h/t·Al,并减轻了劳动强度。
5) electrolyzer voltage
槽电压
1.
The problem of electrolyzer voltage rise by K4Fe(CN)6in refining salt was summarized.
进一步总结了精制盐中K4Fe(CN)6引起的槽电压上升问题,提出了不同运行电流、新旧膜和槽在电压上升中的差异,阐述了加强阳极液酸度控制和原盐中K4Fe(CN)6控制等改进措施。
2.
The reason why the voltage of ion-exchange membrane electrolyzer raises is analyzed and the countermeasures are provided,that is,keeping the electrolyzer temperature in the range of 85~90 ℃,ensuring the electrolyzer voltage steady,reducing the shut-down frequency,improving the salt solution quality,reducing the equipment corrosion and upgrading the inspection and repairing quality.
分析离子膜电解槽电压升高的原因;提出改进措施:控制槽温在85~90℃,保证电压平稳,减少停车次数,提高盐水质量,减少设备腐蚀,提高检修质量。
补充资料:槽电压
槽电压
cell voltage
eood旧nyo槽电压(c ell vohage)电解槽直流电进入点一与出去点之间的电压。在现时广泛采用的水溶液并联制电解的情况下,槽电压实际上就是槽内相邻阴阳二电极间的电压。在生产中,槽电压可以用电压表测量阴、阳一对电极的电压来确定,也可以用直流电源出线和入线间的电压,即供给所有串联电解槽的总电怅F减去导电板的电压降创除以总电解槽数N求得,即: U一乙厂, U.一二‘:丁二一‘川 一佰N式中U格为槽电压,V。槽电压的作用在j二屯服电解的各种阻力和补偿电解电路中的各种电压损失它由以下几个部分电压组成: U梢一U理十U液+U极斗一U接干召泥打隔抢)而U理一E阳一E阴式中口理为电解质的理论分解电压,亦即山电解产物组成的与电解反向的电池电动势,其值等于阳极平衡电位E阳与阴极平衡电位E阴之差;U极为极化超电位;U液、U接、U泥、U隔分别为电流通过电解液、接触点、阳极泥层和隔膜时的电压降。 电解精炼的理论分解电压由阳极粗金属和阴极纯金属的活度比决定,但二者活度实际上相差兀儿,可视为E阳、E阴,即U理、。,所以槽电压仅由式伦)其余各项构成。而电解提取的分解电压在槽电压中占很大比例,其槽电压值比电解精炼高得多,一般约为其1。倍,电能耗相应也约为其10倍。 槽电压与电极反应类型、电流密度、电解液成分和温度、极间距、接触点数目和清洁程度、阳极泥层结构特点、电解持续时间等有关。提高电流密度,降低电解液温度,增大极间距,延长电解时间,增加接触点数日,都会使槽电压升高,导致电解电耗的增大
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条