electrolyser

简明释义

英[ɪˈlɛk.trəˌlaɪ.zər]美[ɪˈlɛk.trəˌlaɪ.zər]

n. 电解槽

英英释义

单词用法

同义词

反义词

例句

1.Both sides of the membrane are coated with a layer of catalyst material, which differs somewhat from the material used in the Electrolyser.

在膜双方都涂有催化剂材料，有点不同，从电解槽中使用的材料层。

2.Both sides of the membrane are coated with a layer of catalyst material, which differs somewhat from the material used in the Electrolyser.

在膜双方都涂有催化剂材料，有点不同，从电解槽中使用的材料层。

3.The solar panels will be used to give energy to the electrolyser to break the molecules of water into hydrogen and oxygen molecules.

太阳能板提供的电能将输出到电解槽以分解水成为氢和氧分子。

4.The ammeter is used to indicate when water should be added to the electrolyser, which is typically after about 80 hours of driving.

电流表是用来指示当水应该被添加到电解槽，通常经过大约80小时的驾驶。

5.This is done through a plastic screw cap on the top of the electrolyser cap (shown clearly in the first photograph).

这是通过一对电解槽盖在第一张照片显示清楚(顶塑料螺帽)。

6.A computerized control and measurement system regulates the operation of the electrolyser and fuel cell.

一套电脑控制和测量系统对电解器和燃料电池进行控制。

7.The cell stack is applicable in the area of PEM fuel cells and PEM water electrolyser cells.

该电池堆可适用于PEM燃料电池和PEM水电解剂电池的领域中。

8.The electrolyser has several stainless steel wire mesh screens above the water surface.

该电解槽有几个以上的水面不锈钢丝网屏幕。

9.The electrolyser circuit is protected by a 30-amp circuit breaker.

该电解槽的电路是被一个30安培的断路器。

10.The new hydrogen production plant uses an advanced electrolyser to split water into hydrogen and oxygen.

这座新的氢气生产厂使用先进的电解槽将水分解为氢气和氧气。

11.Researchers are developing a more efficient electrolyser to reduce energy costs in hydrogen production.

研究人员正在开发一种更高效的电解槽以降低氢气生产的能源成本。

12.The electrolyser technology is crucial for green energy solutions.

该电解槽技术对绿色能源解决方案至关重要。

13.In the lab, we tested the performance of the new electrolyser under different conditions.

在实验室里，我们测试了新型电解槽在不同条件下的性能。

14.The electrolyser can operate on renewable energy sources like solar and wind.

该电解槽可以使用太阳能和风能等可再生能源运行。

作文

In recent years, the importance of sustainable energy sources has become increasingly evident. As the world grapples with the effects of climate change and the depletion of fossil fuels, innovative technologies are being developed to harness clean energy. One such technology that has gained significant attention is the electrolyser, a device that plays a crucial role in the production of hydrogen through the process of electrolysis. Understanding the function and potential of an electrolyser is vital for anyone interested in renewable energy solutions. An electrolyser works by using electricity to split water molecules into hydrogen and oxygen. This process occurs in an electrolytic cell, where the water is subjected to an electric current. When the current passes through the water, it causes the molecules to dissociate, releasing hydrogen gas at the cathode and oxygen gas at the anode. The hydrogen produced can then be used as a clean fuel source, with the only byproduct being water vapor when it is burned or used in fuel cells. The significance of the electrolyser lies in its ability to convert renewable electricity, such as solar or wind energy, into hydrogen. This hydrogen can serve multiple purposes, including powering vehicles, generating electricity, or serving as a feedstock for chemical processes. In this way, the electrolyser not only facilitates the storage of excess renewable energy but also contributes to the decarbonization of various sectors, including transportation and industry. Moreover, the versatility of hydrogen as an energy carrier makes the electrolyser a key component in the transition to a hydrogen economy. Unlike batteries, which have limitations in terms of energy density and charging times, hydrogen can be stored for long periods and transported over long distances. This feature allows for greater flexibility in energy management and distribution, making it an attractive option for balancing supply and demand in the energy market. However, the widespread adoption of electrolysers faces several challenges. One of the primary concerns is the cost associated with the technology. Currently, the production of hydrogen via electrolysis is more expensive than traditional methods, such as steam methane reforming. To make electrolysers more economically viable, ongoing research and development efforts are focused on improving their efficiency and reducing the costs of the materials used in their construction. Additionally, the availability of renewable electricity is crucial for the success of electrolysers. In regions where renewable energy sources are limited, the environmental benefits of hydrogen production may be diminished. Therefore, integrating electrolysers into a broader renewable energy strategy is essential to maximize their potential impact. In conclusion, the electrolyser represents a promising technology in the quest for sustainable energy solutions. By enabling the production of hydrogen from renewable sources, electrolysers can help address some of the most pressing challenges posed by climate change and energy security. As advancements continue to be made in this field, it is crucial for policymakers, researchers, and industry leaders to collaborate and support the development of electrolysers to ensure a cleaner and more sustainable future for all.

近年来，可持续能源的重要性变得越来越明显。随着世界面临气候变化的影响和化石燃料的枯竭，创新技术正在被开发以利用清洁能源。其中一种引起显著关注的技术是电解槽，这是一种在电解过程中通过水分解产生氢气的关键设备。理解电解槽的功能和潜力对于任何对可再生能源解决方案感兴趣的人来说都是至关重要的。 电解槽通过使用电力将水分子分解为氢气和氧气来工作。这个过程发生在一个电解池中，水被施加电流。当电流通过水时，它导致分子解离，在阴极释放氢气，在阳极释放氧气。产生的氢气可以作为清洁燃料来源使用，燃烧或在燃料电池中使用时唯一的副产品是水蒸气。 电解槽的重要性在于它能够将可再生电力（如太阳能或风能）转化为氢气。这种氢气可以用于多种目的，包括为车辆提供动力、发电或作为化学过程的原料。通过这种方式，电解槽不仅促进了过剩可再生能源的储存，还为交通和工业等各个领域的脱碳做出了贡献。 此外，氢气作为能源载体的多功能性使得电解槽成为向氢经济过渡的关键组成部分。与电池相比，氢气在能量密度和充电时间方面的限制较少，可以长期储存并远距离运输。这一特性允许在能源管理和分配中具有更大的灵活性，使其成为平衡能源市场供需的有吸引力的选择。 然而，电解槽的广泛采用面临若干挑战。主要问题之一是与该技术相关的成本。目前，通过电解生产氢气的成本高于传统方法，如蒸汽甲烷重整。为了使电解槽在经济上更具可行性，正在进行的研究和开发工作集中在提高其效率和降低其构建材料的成本。 此外，可再生电力的可用性对电解槽的成功至关重要。在可再生能源有限的地区，氢气生产的环境效益可能会降低。因此，将电解槽整合到更广泛的可再生能源战略中对于最大化其潜在影响至关重要。 总之，电解槽代表了一项在寻找可持续能源解决方案中的有前景的技术。通过使氢气从可再生资源中生产，电解槽可以帮助解决气候变化和能源安全所带来的最紧迫挑战。随着这一领域的不断进步，政策制定者、研究人员和行业领导者之间的合作与支持对于确保一个更清洁、更可持续的未来至关重要。