pyrolysate
简明释义
英[/ˈpaɪrəˌlɪseɪt/]美[/ˈpaɪrəˌlɪseɪt/]
n. 干馏物
英英释义
单词用法
同义词
热解产物 | 热解产物可以用作燃料。 | ||
炭 | 在热解过程中,通常会产生炭。 | ||
生物油 | 从生物质中获得的生物油可以进一步精炼。 |
反义词
水解物 | Hydrolysate is often used in the production of amino acids and proteins. | 水解物常用于氨基酸和蛋白质的生产。 | |
生物质 | Biomass can be converted into energy through various processes. | 生物质可以通过各种过程转化为能源。 |
例句
1.Through detects the reaction products of experiments, shows that the pyrolysate is created in the process.
通过对实验反应产物进行检测,发现实验过程中有热解产物生成。
2.Since the first reported cases, many substances in the pyrolysate have been studied as potentially leading to the leukoencephalopathy but none has been positively identified.
自从首例报道之后,在这些热解物中的许多物质被研究以明确是那种诱发了白质脑病,但尚没有一种被明确肯定。
3.Since the first reported cases, many substances in the pyrolysate have been studied as potentially leading to the leukoencephalopathy but none has been positively identified.
自从首例报道之后,在这些热解物中的许多物质被研究以明确是那种诱发了白质脑病,但尚没有一种被明确肯定。
4.The pyrolysate can be used as a soil amendment to enhance agricultural productivity.
该热解产物可以用作土壤改良剂,以提高农业生产力。
5.The process of converting biomass into energy often involves the collection of the resulting pyrolysate.
将生物质转化为能源的过程通常涉及收集生成的热解产物。
6.The toxicity levels in pyrolysate must be carefully monitored before its application in agriculture.
在农业应用之前,必须仔细监测热解产物中的毒性水平。
7.In waste management, pyrolysate is seen as a potential resource for sustainable energy.
在废物管理中,热解产物被视为可持续能源的潜在资源。
8.Researchers are studying the chemical composition of pyrolysate to improve biofuel production.
研究人员正在研究热解产物的化学成分,以改善生物燃料生产。
作文
The process of pyrolysis has gained significant attention in recent years, particularly in the realm of waste management and renewable energy. Pyrolysis is a thermal decomposition process that occurs in the absence of oxygen, leading to the breakdown of organic materials into simpler compounds. One of the primary products of this process is known as pyrolysate, which refers to the complex mixture of liquids, gases, and solid residues generated during pyrolysis. Understanding pyrolysate is essential for researchers and industries aiming to harness the potential of pyrolysis for sustainable practices.To begin with, the composition of pyrolysate can vary significantly depending on the feedstock used and the conditions under which pyrolysis is conducted. For instance, when biomass such as wood or agricultural residues undergoes pyrolysis, the resulting pyrolysate typically contains bio-oil, syngas, and char. Bio-oil is a liquid product rich in organic compounds, which can be further refined into fuels or chemicals. Syngas, a mixture of hydrogen and carbon monoxide, is a valuable energy source that can be utilized for electricity generation or as a precursor for producing synthetic fuels. Char, the solid residue, can be used as a soil amendment or as a carbon sequestration agent.The utilization of pyrolysate presents numerous advantages. Firstly, it offers a sustainable way to manage waste. By converting organic waste materials into pyrolysate, we can reduce landfill use and lower greenhouse gas emissions associated with waste decomposition. Secondly, the energy content of pyrolysate can be harnessed to produce renewable energy. This is particularly important in the context of climate change, where transitioning to cleaner energy sources is imperative.Moreover, the chemical constituents found in pyrolysate can serve as building blocks for various industrial applications. For example, certain compounds derived from bio-oil can be used to manufacture bioplastics or other biodegradable materials, contributing to the reduction of plastic pollution. Additionally, the versatility of pyrolysate allows for its application in different sectors, from agriculture to pharmaceuticals, showcasing its potential to drive innovation.However, challenges remain in the widespread adoption of pyrolysis technology and the effective utilization of pyrolysate. One major hurdle is the need for advanced technologies to optimize the pyrolysis process, ensuring maximum yield and quality of the pyrolysate. Furthermore, regulatory frameworks must be established to address safety and environmental concerns associated with pyrolysis facilities.In conclusion, the exploration of pyrolysate and its applications is a promising avenue for advancing sustainability and resource efficiency. As we continue to seek solutions to pressing environmental issues, understanding the intricacies of pyrolysate will be crucial for unlocking its full potential. By investing in research and development, we can pave the way for innovative approaches to waste management and energy production that benefit both society and the planet.
热解过程近年来在废物管理和可再生能源领域引起了显著关注。热解是一种在缺氧条件下发生的热分解过程,导致有机材料分解为更简单的化合物。该过程的主要产品之一被称为pyrolysate,它指的是在热解过程中生成的液体、气体和固体残留物的复杂混合物。理解pyrolysate对研究人员和希望利用热解潜力进行可持续实践的行业至关重要。首先,pyrolysate的组成可能因所用原料和热解条件的不同而显著变化。例如,当生物质如木材或农业残余物经历热解时,产生的pyrolysate通常包含生物油、合成气和炭。生物油是一种富含有机化合物的液体产品,可以进一步精炼成燃料或化学品。合成气是氢气和一氧化碳的混合物,是一种有价值的能源来源,可以用于发电或作为合成燃料的前体。炭,作为固体残留物,可以用作土壤改良剂或碳封存剂。利用pyrolysate带来了许多优势。首先,它提供了一种可持续的废物管理方式。通过将有机废物转化为pyrolysate,我们可以减少填埋场的使用,并降低与废物分解相关的温室气体排放。其次,pyrolysate的能量含量可以被利用来生产可再生能源。这在应对气候变化的背景下尤为重要,因为向更清洁的能源来源过渡是必不可少的。此外,pyrolysate中发现的化学成分可以作为各种工业应用的基础。例如,从生物油中提取的某些化合物可以用于制造生物塑料或其他可降解材料,帮助减少塑料污染。此外,pyrolysate的多功能性使其在农业到制药等不同领域都有应用,展示了其推动创新的潜力。然而,在热解技术的广泛采用和pyrolysate的有效利用方面仍然存在挑战。一个主要障碍是需要先进技术来优化热解过程,以确保最大产量和pyrolysate的质量。此外,必须建立监管框架,以解决与热解设施相关的安全和环境问题。总之,探索pyrolysate及其应用是推动可持续性和资源效率的有前景的途径。随着我们继续寻求解决紧迫环境问题的方案,理解pyrolysate的复杂性对于释放其全部潜力至关重要。通过投资于研究和开发,我们可以为废物管理和能源生产开辟创新的方法,造福社会和地球。