sulphating
简明释义
n. 硫酸酯化;硫酸盐化;硫酸垢
v. 使与硫酸化合;使在蓄电池极板上形成含硫酸铅的鳞状沉淀物;硫酸盐化;被鳞状硫酸铅的沉淀物覆盖(sulphate 的 ing 形式)
英英释义
The process of treating or reacting with sulfur or its compounds, often resulting in the formation of sulfate. | 与硫或其化合物反应或处理的过程,通常导致硫酸盐的形成。 |
单词用法
硫酸铵;硫酸氨 | |
[化]硫酸钙 |
同义词
反义词
| 脱硫 | Desulphating is essential for improving battery performance. | 脱硫对提高电池性能至关重要。 | |
| 中和 | The process of neutralization can help balance pH levels in soil. | 中和过程可以帮助平衡土壤的pH值。 |
例句
1.The results of orthogonal experiment in sulphating roasting process showed that sulfuric acid consumption affected the leaching rate significantly, then temperature and time.
通过对酸化焙烧进行正交实验发现:硫酸用量为最重要影响因素,温度和时间次之。
2.The results of orthogonal experiment in sulphating roasting process showed that sulfuric acid consumption affected the leaching rate significantly, then temperature and time.
通过对酸化焙烧进行正交实验发现:硫酸用量为最重要影响因素,温度和时间次之。
3.The technician explained how sulphating affects the lifespan of the battery.
技术员解释了sulphating(硫酸化)如何影响电池的使用寿命。
4.The process of sulphating is essential in lead-acid batteries to improve their efficiency.
在铅酸电池中,sulphating(硫酸化)过程对提高其效率至关重要。
5.During the testing phase, we noticed signs of sulphating on the battery plates.
在测试阶段,我们注意到电池板上有sulphating(硫酸化)的迹象。
6.To prevent sulphating, regular maintenance of the battery is necessary.
为了防止sulphating(硫酸化),定期维护电池是必要的。
7.Excessive sulphating can lead to battery failure and reduced performance.
过度的sulphating(硫酸化)可能导致电池故障和性能下降。
作文
In the field of chemistry and environmental science, the term sulphating refers to a process that involves the addition of sulfate groups to various compounds. This process is significant in both natural and industrial contexts. For instance, in nature, sulphating occurs during the breakdown of organic matter, where sulfur compounds are released into the environment. These compounds can then react with other elements, leading to the formation of sulfates that are crucial for plant growth. In this way, sulphating plays an essential role in the nutrient cycle, enriching the soil and supporting ecosystems.In industrial applications, sulphating is often used in the production of fertilizers and chemicals. The process allows for the transformation of raw materials into more useful products. For example, during the manufacture of phosphoric acid, sulphating is employed to convert phosphate rock into a form that can be easily absorbed by plants. This highlights how sulphating not only facilitates chemical reactions but also contributes to agricultural productivity.However, sulphating is not without its challenges. In certain contexts, excessive sulphating can lead to environmental issues, particularly in water bodies. When sulfates leach into rivers and lakes, they can contribute to the phenomenon known as eutrophication. This process results in algal blooms that deplete oxygen levels in the water, harming aquatic life. Therefore, while sulphating is a vital process, it must be managed carefully to prevent negative ecological impacts.Moreover, the concept of sulphating extends beyond just chemical processes; it also has implications in the field of energy storage. In lead-acid batteries, sulphating refers to the formation of lead sulfate crystals during the discharge cycle. If these crystals grow too large, they can hinder the battery's performance and lifespan. Understanding the mechanisms of sulphating in this context is crucial for developing better battery technologies and ensuring efficient energy storage solutions.In conclusion, sulphating is a multifaceted term that encompasses various processes in both nature and industry. It is integral to nutrient cycles, agricultural practices, and even energy storage technologies. However, it is important to recognize the potential downsides of sulphating, particularly in environmental contexts. As we continue to explore and understand this process, we must strive to balance its benefits with the need for sustainable practices. By doing so, we can harness the positive aspects of sulphating while minimizing its adverse effects on our planet. Overall, the study of sulphating reveals much about the interconnectedness of chemical processes and their impact on our world.
在化学和环境科学领域,术语sulphating指的是将硫酸根添加到各种化合物中的过程。这个过程在自然和工业环境中都具有重要意义。例如,在自然界中,sulphating发生在有机物质分解过程中,硫化合物释放到环境中。这些化合物可以与其他元素反应,形成对植物生长至关重要的硫酸盐。通过这种方式,sulphating在营养循环中发挥着重要作用,丰富土壤并支持生态系统。在工业应用中,sulphating通常用于肥料和化学品的生产。该过程使原材料转化为更有用的产品。例如,在磷酸的制造过程中,sulphating被用来将磷矿石转化为植物易于吸收的形式。这突显了sulphating不仅促进化学反应,还对农业生产力做出贡献。然而,sulphating并非没有挑战。在某些情况下,过量的sulphating可能会导致环境问题,特别是在水体中。当硫酸盐渗入河流和湖泊时,它们可能会导致被称为富营养化的现象。这个过程导致藻类大量繁殖,消耗水中的氧气,危害水生生物。因此,尽管sulphating是一个重要的过程,但必须谨慎管理,以防止对生态产生负面影响。此外,sulphating的概念不仅限于化学过程;它在能源存储领域也具有重要意义。在铅酸电池中,sulphating指的是在放电周期中形成的铅硫酸盐晶体。如果这些晶体生长得过大,可能会影响电池的性能和使用寿命。了解sulphating在这一背景下的机制对于开发更好的电池技术和确保高效的能源存储解决方案至关重要。总之,sulphating是一个多方面的术语,涵盖了自然和工业中的各种过程。它对营养循环、农业实践甚至能源存储技术至关重要。然而,重要的是要认识到sulphating的潜在缺点,特别是在环境背景下。随着我们继续探索和理解这一过程,我们必须努力平衡其好处与可持续实践的需要。通过这样做,我们可以利用sulphating的积极方面,同时最小化其对我们星球的不利影响。总体而言,研究sulphating揭示了化学过程的相互联系及其对我们世界的影响。
