carbonisation

简明释义

英[ˌkɑːrbənaɪˈzeɪʃən]美[ˌkɑːrbənaɪˈzeɪʃən]

n. 碳化，碳化作用

英英释义

单词用法

同义词

反义词

例句

1.Carbonisation is the thermal process for the conversion of coal into coke, involving heating coal at high temperature for many hours in the absence of air whilst contained in ovens.

焦化作用是将煤转化为焦炭的热处理过程，涉及到将煤在焦炭炉中隔绝空气高温加热数小时。

2.By the use of the Deep-Shaft-Carbonisation also wet biomass and bio-waste can be transformed into coal with a carbon yield of almost 100%.

通过采用深竖井碳化技术，湿生物质和生物废料可以被转化成可以产出将近100%碳的煤。

3.Drying, low-temperature carbonisation, and cracking of gases occur in the upper zone, while permanent gasification of charcoal takes in lower zone.

干燥，低温碳化和气体打击发生在上层，而永久气化木炭在较低的地带占地。

4.In order to manufacture complex components, it is suggested that at least two semi-finished moulded parts are firmly joined either in raw form or after at least partial carbonisation.

为了制造复杂的部件建议，将至少两个半成品成形件或者以毛坯或者在至少部分地碳化以后材料连接地接合。

5.The thermal post-combustion is used for two oven Chambers, one of which operates in a pyrolysis or carbonisation mode and the other operates in the form of a combustion chamber.

根据本发明，热学后燃烧用于两个燃烧腔，其一以热解或碳化形式进行，另一个作为燃烧腔形式操作。

6.Then, the carbon parts are available after carbonisation of the moulded parts in non-oxidizing atmosphere.

然后在成形件碳化后在非氧化的氛围中作为碳部件供使用。

7.In order to manufacture complex components, it is suggested that at least two semi-finished moulded parts are firmly joined either in raw form or after at least partial carbonisation.

为了制造复杂的部件建议，将至少两个半成品成形件或者以毛坯或者在至少部分地碳化以后材料连接地接合。

8.Researchers are studying the carbonisation 碳化 of biomass as a renewable energy source.

研究人员正在研究生物质的碳化作为可再生能源。

9.The carbonisation 碳化 of fossil fuels contributes significantly to climate change.

化石燃料的碳化对气候变化有显著影响。

10.The carbonisation 碳化 of waste materials can help reduce landfill usage.

废弃物的碳化可以帮助减少垃圾填埋场的使用。

11.The process of carbonisation 碳化 transforms organic materials into carbon-rich products.

碳化的过程将有机材料转化为富含碳的产品。

12.In ancient times, the carbonisation 碳化 of wood was used to create charcoal for cooking.

在古代，木材的碳化被用来制作烹饪用的木炭。

作文

The process of carbonisation is a fascinating and essential aspect of material science and environmental studies. In simple terms, carbonisation refers to the chemical transformation of organic materials into carbon-rich substances through the application of heat in the absence of oxygen. This process has been utilized for centuries, primarily in the production of charcoal from wood, but its applications extend far beyond traditional uses. Understanding carbonisation is crucial for various industries, including energy production, waste management, and even agriculture.One of the most significant benefits of carbonisation is its role in energy production. As global energy demands rise, there is an increasing need for sustainable and renewable energy sources. Biomass, which includes organic materials such as agricultural residues, forestry waste, and even municipal solid waste, can be converted into biochar through carbonisation. Biochar is a stable form of carbon that can be used as a soil amendment, enhancing soil fertility and improving water retention. Additionally, the process of carbonisation captures carbon that would otherwise be released into the atmosphere, thus contributing to climate change mitigation efforts.Moreover, carbonisation plays a vital role in waste management. With the growing concern over landfill waste and its environmental impact, converting organic waste into biochar through carbonisation offers a viable solution. By diverting organic waste from landfills, we not only reduce methane emissions—a potent greenhouse gas—but also create a valuable product that can be used in agriculture and landscaping. This closed-loop approach exemplifies how carbonisation can contribute to a circular economy, where waste is minimized and resources are reused effectively.In addition to its environmental benefits, carbonisation has significant implications for agriculture. The addition of biochar to soils can improve crop yields by enhancing nutrient availability and promoting beneficial microbial activity. Farmers and researchers around the world are increasingly recognizing the potential of carbonisation as a tool for sustainable agriculture. By integrating biochar into farming practices, we can not only improve food security but also enhance soil health, making it more resilient to climate change impacts.Despite its numerous advantages, carbonisation is not without challenges. The process requires careful management of temperature and conditions to ensure the desired quality of the end product. Additionally, there is a need for further research to optimize carbonisation methods for different feedstocks and to understand the long-term effects of biochar application on soil ecosystems. Policymakers and industry stakeholders must work together to address these challenges and promote the adoption of carbonisation technologies.In conclusion, carbonisation is a vital process with far-reaching implications for energy production, waste management, and agriculture. As we face the pressing challenges of climate change and resource depletion, understanding and harnessing the power of carbonisation will be essential for creating a sustainable future. By embracing this innovative approach, we can transform waste into valuable resources, enhance soil health, and contribute to a cleaner, greener planet. The journey towards a sustainable future is complex, but with processes like carbonisation, we have the potential to make significant strides toward achieving our environmental goals.

碳化过程是材料科学和环境研究中一个迷人且重要的方面。简单来说，carbonisation指的是通过在缺氧条件下加热有机材料，使其转化为富含碳的物质的化学过程。这个过程已经被利用了几个世纪，主要用于从木材生产木炭，但其应用远不止于传统用途。理解carbonisation对各个行业至关重要，包括能源生产、废物管理，甚至农业。carbonisation的一个显著好处是它在能源生产中的作用。随着全球能源需求的上升，迫切需要可持续和可再生的能源来源。生物质，包括农业残余、林业废物，甚至市政固体废物，可以通过carbonisation转化为生物炭。生物炭是一种稳定的碳形式，可以用作土壤改良剂，提高土壤肥力和改善水分保持能力。此外，carbonisation过程捕获了本来会释放到大气中的碳，从而有助于减缓气候变化。此外，carbonisation在废物管理中也发挥着重要作用。随着对填埋废物及其环境影响的日益关注，通过carbonisation将有机废物转化为生物炭提供了一种可行的解决方案。通过将有机废物从填埋场转移，我们不仅减少了甲烷排放（一种强效的温室气体），还创造了可以用于农业和园艺的有价值的产品。这种闭环方法示范了carbonisation如何有助于循环经济，其中废物最小化，资源有效再利用。除了环境益处，carbonisation对农业也有重大影响。将生物炭添加到土壤中可以通过提高养分可用性和促进有益微生物活动来改善作物产量。世界各地的农民和研究人员越来越认识到carbonisation作为可持续农业工具的潜力。通过将生物炭纳入农业实践，我们不仅可以改善粮食安全，还可以增强土壤健康，使其更能抵御气候变化的影响。尽管有众多优点，carbonisation并非没有挑战。该过程需要对温度和条件进行仔细管理，以确保最终产品的质量。此外，需要进一步研究以优化不同原料的carbonisation方法，并了解生物炭施用对土壤生态系统的长期影响。政策制定者和行业利益相关者必须共同努力，解决这些挑战，促进carbonisation技术的采用。总之，carbonisation是一个至关重要的过程，对能源生产、废物管理和农业具有深远的影响。随着我们面临气候变化和资源枯竭的紧迫挑战，理解和利用carbonisation的力量将对创造可持续的未来至关重要。通过采用这种创新的方法，我们可以将废物转化为有价值的资源，改善土壤健康，并为更清洁、更绿色的星球做出贡献。通往可持续未来的旅程是复杂的，但通过像carbonisation这样的过程，我们有潜力在实现环境目标方面取得重大进展。