pyrolytic

简明释义

英[ˌpaɪˈrɒlɪtɪk]美[ˌpaɪroʊˈlɪtɪk]

adj. 热解的

英英释义

单词用法

同义词

反义词

例句

1.Major ingredients of pyrolytic tar of larch bark were studied by advanced analysis methods such as FTIR, DTA and GC-MS.

利用红外光谱、差热扫描以及气相色谱—质谱联用等先进的分析手段对落叶松树皮快速热解油的主要成分进行了分析。

2.The research results obtained can offer an important reference for realizing a continuous and reliable biomass pyrolytic liquefaction process.

实验结果对实现生物质连续可靠的热解液化生产过程具有重要的参考价值。

3.We test the whole system and use this system, the structure graphics of the Highly Oriented Pyrolytic Graphite (HOPG) and the gold surface are gained successfully.

对整个系统进行了联合调试，成功获得高定向热解石墨和金表面的结构图像。

4.The effects of pyrolytic and chromatographic conditions on analysis were studied and discussed.

研究和讨论了裂解和色谱条件对分析的影响。

5.The former two types are brittle ones, and the fracture strain of pyrolytic carbon matrix is the controlling factor of the strength.

前两种为脆性断裂方式，热解炭基体的断裂应变是这类材料强度的控制因素。

6.The formed pyrolytic products have nearly 50 compounds.

纤维素裂解产生近50个裂解产物；

7.But pyrolytic stoves produce almost no soot-the carbon is all locked into the biochar.

但是热分解炉几乎不产生黑烟，碳全都锁在了生物炭中。

8.A rotating cone shaped reactor has been designed for studying pyrolytic process of coal particles mixed with a heat carrying medium.

转锥式生物质闪速热解液化装置是当今研究的一个热点，而该技术的核心就是对旋转锥设计。

9.A self made graphite platform was installed in pyrolytic graphite tube of graphite furnace.

用自制的石墨平台安装于石墨炉中热解石墨管内。

10.In the laboratory, scientists conducted experiments using pyrolytic techniques to analyze chemical compounds.

在实验室，科学家们使用热解技术进行实验以分析化合物。

11.The pyrolytic decomposition of plastics can significantly reduce landfill waste.

塑料的热解分解可以显著减少填埋废物。

12.Researchers are exploring pyrolytic methods for producing biofuels from agricultural waste.

研究人员正在探索从农业废弃物中生产生物燃料的热解方法。

13.The waste management facility uses a pyrolytic process to convert organic materials into energy.

该废物管理设施使用热解过程将有机材料转化为能源。

14.The pyrolytic carbon produced during the process is used in various industrial applications.

在该过程中产生的热解碳用于各种工业应用。

作文

In recent years, the field of materials science has seen significant advancements, particularly in the development of innovative methods for waste management and energy production. One such method that has gained attention is the process known as pyrolytic decomposition. This technique involves the thermal degradation of organic materials in the absence of oxygen, resulting in the conversion of biomass into valuable products such as bio-oil, syngas, and char. The term pyrolytic refers specifically to this type of thermal treatment, which is crucial for transforming waste materials into useful resources.The importance of pyrolytic processes cannot be overstated, especially in the context of global environmental challenges. With increasing amounts of waste being generated worldwide, effective waste management strategies are essential. Traditional methods, such as landfilling and incineration, often lead to pollution and greenhouse gas emissions. In contrast, pyrolytic technology offers a cleaner alternative by minimizing harmful emissions and recovering energy from waste.One of the most promising aspects of pyrolytic processes is their ability to convert various types of feedstock, including agricultural residues, municipal solid waste, and even plastic waste, into valuable energy sources. For example, when agricultural waste is subjected to pyrolytic treatment, it can yield bio-oil that can be further refined into transportation fuels or chemicals. This not only helps reduce the volume of waste but also contributes to energy sustainability by providing renewable energy options.Moreover, the char produced during pyrolytic decomposition can be utilized as a soil amendment, improving soil health and carbon sequestration. This dual benefit of producing both energy and enhancing soil quality makes pyrolytic processes particularly attractive for sustainable agricultural practices.Despite the advantages of pyrolytic technologies, there are still challenges to overcome. The economic feasibility of implementing pyrolytic systems on a large scale remains a critical concern. Initial capital costs, operational complexities, and the need for specialized equipment can deter potential investors. Additionally, further research is needed to optimize the pyrolytic process parameters to maximize yield and quality of the products.In conclusion, pyrolytic technology represents a promising solution for addressing waste management and energy production challenges. By converting waste into valuable resources, it not only mitigates environmental issues but also paves the way for a more sustainable future. As research and development in this field continue to progress, it is imperative that we explore the full potential of pyrolytic processes to create a circular economy that benefits both society and the planet.

近年来，材料科学领域取得了显著进展，特别是在废物管理和能源生产的创新方法开发方面。其中一种引起关注的方法是被称为热解分解的过程。这种技术涉及在缺氧条件下对有机材料进行热降解，从而将生物质转化为有价值的产品，如生物油、合成气和炭。术语热解特指这种类型的热处理，对于将废物材料转化为有用资源至关重要。热解过程的重要性不容小觑，特别是在全球环境挑战的背景下。随着全球废物产生量的增加，有效的废物管理策略至关重要。传统的方法，如填埋和焚烧，往往导致污染和温室气体排放。相比之下，热解技术通过最小化有害排放并从废物中回收能量，提供了一种更清洁的替代方案。热解过程最有前景的一个方面是其能够将各种类型的原料转化为有价值的能源来源，包括农业残余、城市固体废物，甚至塑料废物。例如，当农业废物经过热解处理时，可以产生生物油，进一步精炼后可用于交通燃料或化学品。这不仅有助于减少废物体积，还通过提供可再生能源选项来促进能源可持续性。此外，在热解分解过程中产生的炭可以用作土壤改良剂，改善土壤健康和碳封存。这种生产能源和改善土壤质量的双重好处使得热解过程在可持续农业实践中尤为吸引人。尽管热解技术具有优势，但仍然面临一些挑战。大规模实施热解系统的经济可行性仍然是一个关键问题。初始资本成本、操作复杂性以及对专业设备的需求可能会阻碍潜在投资者。此外，仍需进一步研究以优化热解过程参数，以最大化产品的产量和质量。总之，热解技术代表了解决废物管理和能源生产挑战的有希望的解决方案。通过将废物转化为有价值的资源，它不仅减轻了环境问题，还为更可持续的未来铺平了道路。随着这一领域的研究和发展不断进展，我们必须探索热解过程的全部潜力，以创造一个既惠及社会又造福地球的循环经济。