water electrolysis

美 [ˈwɔːtər ɪˌlekˈtrɑːləsɪs]英 [ˈwɔːtə(r) ɪˌlekˈtrɒləsɪs]
  • 网络水电解;电解水
water electrolysiswater electrolysis
  1. Hydrogen generating system by water electrolysis is one of the most important hydrogen generating methods , and the system is widely used for thermal power plant , nuclear power plant , and for feed-oxygen in obturating space such as nuclear submarines and space station .

    水电解制氢是重要的制氢方法之一,它广泛用于热电厂、核电站以及核潜艇、航天空间站等密闭空间人员供氧。

  2. Design of Fuzzy Control Loop on Temperature for Hydrogen Generation System by Water Electrolysis

    水电解制氢温度模糊控制系统的设计

  3. Preparation Method of Alkali Solution for water Electrolysis Hydrogen - Producing Equipment

    水电解制氢设备的碱液配制方法

  4. Issues to Be Noted in Using of Water Electrolysis Hydrogen Preparation Equipment

    水电解制氢设备在使用中应注意的问题

  5. Development of prototype devices of alkaline polymer electrolyte water electrolysis .

    碱性聚合物电解质水电解器原型的研制。

  6. Development of Ni evolution oxygen electrode for water electrolysis

    电解水Ni析O2电极的研制

  7. The design calculation and failure analysis of feed-water in hydrogen generating system by water electrolysis

    水电解制氢(氧)装置补水故障分析及设计计算

  8. Progress of hydrogen production through water electrolysis

    电解水制氢技术进展

  9. Reason of level imbalance and deal with step about hydrogen production plant by water electrolysis

    水电解制氢装置液位偏差成因及其处理措施

  10. The dynamic equation and the calculation methods of impurity hydrogen during high concentration heavy water electrolysis

    高浓重水电解过程中杂质氢的动态变化方程与计算方法

  11. The new DSA for alkaline water electrolysis has higher catalytic activity and longer life time .

    这种新型表面活性层用于碱性水电解时具有析氧催化活性高,稳定性好等特点。

  12. Development of nickel alloys as HER cathodes for water electrolysis

    镍合金用作电解水析氢阴极的发展现状

  13. Research progress in decreasing the anodic overpotential for oxygen evolution in water electrolysis

    降低水电解中阳极析氧过电位的研究进展

  14. Practice of power peak load shifting in hydrogen productio by water electrolysis

    电解制氢过程中削峰填谷实践

  15. Application of sintered platinum-iridium alloy electrode in water electrolysis device

    烧结铂铱合金电极在电解水装置中的应用

  16. Review of solid polymer electrolyte water electrolysis

    固体聚合物水电解技术综述

  17. Explanation of Several Behaviors of Voltage-controlled Friction with the Mechanism of the Water Electrolysis

    用一种新的机理解释电控摩擦效应的几个规律

  18. Optimization of membrane electrodes for SPE water electrolysis

    固体聚合物电解质水电解池电极的优化研究

  19. Application of Non-asbestos Membrane for Alkaline Water Electrolysis

    无石棉隔膜在碱性电解水领域的应用

  20. Deuterium generating by heavy water electrolysis is one of the most important generating deuterium methods .

    电解重水制氘是生产高纯氘的重要方法之一。

  21. A novel diaphragm for alkaline water electrolysis

    一种碱性水电解用新型隔膜

  22. Study on SPE water electrolysis performance of Nafion / PTFE composite membranes with different thicknesses

    不同厚度PTFE增强复合膜的SPE水电解性能

  23. Recent Development of Ni-base Alloy as a Cathode Materials for the Production of Hydrogen by Alkaline Water Electrolysis

    碱性电解水制氢镍合金阴极材料的研究进展

  24. The application of a cation exchange membrane in hydrogen generation by water electrolysis has been studied in this article .

    本文研究了阳离子交换膜在碱性条件下电解制氢中的应用。

  25. The system for water electrolysis device practical , reliable , safe , vehicle-mounted water electrolysis device for the application .

    本系统对于电解水装置实用,可靠,安全,适用车载式水电解器的应用。

  26. Amorphous Ni-Mo-Fe Alloy as the Electrode for Hydrogen Evolution Reaction of Alkaline Water Electrolysis

    非晶态Ni-Mo-Fe合金作电解水析氢反应电极

  27. The sunhydro station makes its hydrogen on site with solar power through a process called water electrolysis .

    这个加氢站是利用太阳能,通过所谓的水电解工艺来制氢的。

  28. These lay the necessary theory foundation for the research of heavy water electrolysis and the production of high purity deuterium .

    为研究重水电解及高纯氘的制取奠定了必要的理论基础。

  29. During water electrolysis , electric power consumption could be reduced considerably by adding additives and moving at low current density .

    在电解过程中加入添加剂和采取低电流密度运行,可大幅度降低电能消耗。

  30. Matching the water electrolysis hydrogen to cause the element use ratio reach 100 % and CO2 zero discharges ;

    再配入水电解氢使元素利用率达100%并CO2零排放;