gasify

简明释义

英[ˈɡæsɪˌfaɪ]美[ˈɡæsəˌfai]

vt. 使气化，使成为气体

vi. 气化，成为气体

第 三 人 称 单 数 g a s i f i e s

现 在 分 词 g a s i f y i n g

过 去 式 g a s i f i e d

过 去 分 词 g a s i f i e d

英英释义

单词用法

同义词

反义词

例句

1.The circulating fluid bed technology is used to gasify cheap pulverized coal, and by rational organization of the process flow the production cost of urea can be decreased.

利用循环流化床技术气化廉价的粉煤，通过合理组织流程，可降低尿素生产成本。

2.The circulating fluid bed technology is used to gasify cheap pulverized coal, and by rational organization of the process flow the production cost of urea can be decreased.

利用循环流化床技术气化廉价的粉煤，通过合理组织流程，可降低尿素生产成本。

3.It has been proved that the formed coke is qualified to be used as industrial gasification coal that produces gas with the formed coke in the moving bed gasify furnace.

通过在移动床气化炉的造气实验表明，该气化型焦完全符合工业化造气用煤要求，可替代焦炭作为生产半水煤气的原料。

4.But there had been little incentive for the global chemical industry to gasify coal until prices began soaring for natural gas and oil.

但是直到天然气和石油的价格大幅上涨之后，全球化学工业才有了开展煤炭气化业务的动力。

5.Mr Buzek pins his hopes on techniques to liquefy or gasify coal, but they are not yet developed.

Buzek先生既希望于煤炭的液化和气化技术，但至今尚未突破。

6.Rice husk with ash contents above 20% is difficult to gasify.

水稻20%以上灰分含量的壳很难气化。

7.The process of burning coal can be modified to gasify 气化 it into a cleaner fuel.

燃烧煤的过程可以被修改为将其气化成更清洁的燃料。

8.Researchers are working on techniques to gasify 气化 biomass for sustainable energy production.

研究人员正在开发技术以将生物质气化用于可持续能源生产。

9.In the gasification process, organic materials are heated to high temperatures to gasify 气化 them.

在气化过程中，有机材料被加热到高温以使其气化。

10.The new plant will gasify 气化 waste materials to generate electricity.

新工厂将对废弃物进行气化以发电。

11.The technology used to gasify 气化 natural gas is crucial for reducing emissions.

用于气化天然气的技术对于减少排放至关重要。

作文

In recent years, the concept of energy transformation has gained significant attention due to the increasing demand for sustainable energy solutions. One method that has emerged as a viable option is the process to gasify (气化) organic materials such as biomass or coal. This process involves converting solid or liquid fuels into gas, which can then be used for various energy applications. The ability to gasify (气化) materials not only enhances energy efficiency but also reduces harmful emissions associated with traditional combustion methods. The gasification (气化) process begins by heating the feedstock in a low-oxygen environment. This controlled atmosphere prevents complete combustion and allows for the breakdown of complex organic compounds into simpler gaseous forms. The primary products of gasification (气化) are syngas, which primarily consists of hydrogen and carbon monoxide. This syngas can be utilized directly for electricity generation or further processed into fuels such as methanol or synthetic natural gas. One of the most significant advantages of gasifying (气化) biomass is its potential to utilize waste materials that would otherwise contribute to environmental pollution. Agricultural residues, wood chips, and even municipal solid waste can be converted into valuable energy resources. By implementing gasification (气化) technologies, communities can reduce landfill usage while simultaneously generating clean energy. This circular approach not only addresses waste management challenges but also promotes energy independence. Moreover, the gasification (气化) process can be integrated with carbon capture and storage (CCS) technologies. By capturing the carbon dioxide produced during gasification (气化), we can significantly mitigate the greenhouse gas emissions associated with fossil fuel use. This combination of gasification (气化) and CCS presents a promising pathway toward achieving net-zero emissions in the energy sector. Despite its numerous benefits, the widespread adoption of gasification (气化) technologies faces several challenges. The initial investment required for gasification (气化) plants can be substantial, and the technology may not yet be economically viable in all regions. Additionally, public perception and regulatory frameworks can influence the deployment of gasification (气化) systems. Therefore, it is essential for policymakers to create supportive environments that encourage innovation and investment in this field. In conclusion, the ability to gasify (气化) organic materials presents a transformative opportunity for the future of energy production. By harnessing waste and reducing emissions, gasification (气化) technologies can play a crucial role in transitioning to a more sustainable energy landscape. As research and development continue to advance, it is vital for stakeholders across various sectors to collaborate and promote the implementation of gasification (气化) solutions. This collective effort will be instrumental in addressing the pressing energy challenges of our time and ensuring a cleaner, greener future for generations to come.

近年来，由于对可持续能源解决方案的需求不断增加，能源转型的概念引起了广泛关注。其中一个出现的可行方法是将有机材料如生物质或煤炭进行气化（gasify）。这一过程涉及将固体或液体燃料转化为气体，然后可用于各种能源应用。气化（gasify）材料的能力不仅提高了能源效率，而且减少了与传统燃烧方法相关的有害排放。 气化（gasification）过程开始时，在低氧环境中加热原料。这种控制的气氛防止了完全燃烧，并允许将复杂的有机化合物分解为更简单的气体形式。气化（gasification）的主要产品是合成气，主要由氢气和一氧化碳组成。这种合成气可以直接用于发电，或者进一步加工成甲醇或合成天然气。 气化（gasifying）生物质的一个重要优势是其利用本来会造成环境污染的废物材料的潜力。农业残留物、木屑甚至市政固体废物都可以转化为有价值的能源资源。通过实施气化（gasification）技术，社区可以减少填埋场的使用，同时生成清洁能源。这种循环的方法不仅解决了废物管理挑战，还促进了能源独立。 此外，气化（gasification）过程可以与碳捕获和储存（CCS）技术相结合。通过捕获在气化（gasification）过程中产生的二氧化碳，我们可以显著减轻与化石燃料使用相关的温室气体排放。气化（gasification）和CCS的结合为实现能源部门的净零排放提供了一条有前景的途径。 尽管有诸多好处，气化（gasification）技术的广泛采用面临一些挑战。建立气化（gasification）工厂所需的初始投资可能很大，并且该技术在所有地区尚未经济可行。此外，公众认知和监管框架也会影响气化（gasification）系统的部署。因此，政策制定者必须创造支持性的环境，以鼓励在这一领域的创新和投资。 总之，能够气化（gasify）有机材料为未来的能源生产提供了变革性的机会。通过利用废物并减少排放，气化（gasification）技术可以在过渡到更可持续的能源格局中发挥关键作用。随着研究和开发的不断推进，各个行业的利益相关者必须合作，促进气化（gasification）解决方案的实施。这种集体努力将对解决我们时代迫切的能源挑战至关重要，并确保为后代创造一个更清洁、更绿色的未来。