pyrolyzer

简明释义

英[pɪˈrɒlaɪzə(r)]美[pɪˈrɑːlaɪzər]

n. 裂解炉；热解器

英英释义

单词用法

同义词

反义词

例句

1.To accurately describe the fuel combustion and radiative heat transfer processes in furnaces is very crucial in comprehensive numerical simulation of ethylene pyrolyzer.

在乙烯裂解炉综合模拟研究中，准确地描述炉膛内燃料燃烧和辐射传热过程极其重要。

2.To accurately describe the fuel combustion and radiative heat transfer processes in furnaces is very crucial in comprehensive numerical simulation of ethylene pyrolyzer.

在乙烯裂解炉综合模拟研究中，准确地描述炉膛内燃料燃烧和辐射传热过程极其重要。

3.The main and complex process in a pyrolyzer include flow, combustion, pyrolysis reaction and heat transfer.

乙烯裂解炉内包括了复杂的流体流动、燃烧反应、裂解反应以及热量传递等过程。

4.The tubular reactor of Daqing naphtha pyrolyzer is simulated by a two-dimensional model.

对大庆石脑油裂解炉反应管用二维模型进行数学模拟。

5.Waste printed circuit board(PCB) was pyrolyzed in a self-developed fixed bed batch vacuum pyrolyzer and the pyrolysis products were analyzed.

在自行设计的间歇式固定床真空热解装置中热解废印制线路板（PCB），对热解产物进行了分析。

6.The process of adding hydrogen gas in fuel gas of ethylidene chloride pyrolyzer and its effects were introduced.

介绍了在二氯乙烷裂解炉燃料气中添加氢气的工艺过程和效果。

7.Researchers are studying the performance of a pyrolyzer 热解炉 for recycling plastics.

研究人员正在研究一种pyrolyzer 热解炉在塑料回收中的性能。

8.The design of the pyrolyzer 热解炉 allows for better heat recovery and efficiency.

该pyrolyzer 热解炉的设计使得热量回收和效率更好。

9.Using a pyrolyzer 热解炉, we can produce renewable energy from agricultural residues.

通过使用pyrolyzer 热解炉，我们可以从农业废弃物中生产可再生能源。

10.The pyrolyzer 热解炉 operates at high temperatures to break down materials without combustion.

pyrolyzer 热解炉在高温下运行，以无燃烧的方式分解材料。

11.The new pyrolyzer 热解炉 can efficiently convert organic waste into biochar.

新的pyrolyzer 热解炉可以高效地将有机废物转化为生物炭。

作文

In recent years, the importance of renewable energy sources has become increasingly evident. One of the innovative technologies that have emerged in this field is the use of a pyrolyzer（热解炉）. A pyrolyzer is a device that thermally decomposes organic materials at high temperatures in the absence of oxygen, resulting in the production of biochar, syngas, and bio-oil. This process is known as pyrolysis, and it presents a sustainable method for waste management and energy production.The working principle of a pyrolyzer involves heating organic materials such as biomass, plastics, or even tires to temperatures typically between 300°C and 900°C. During this process, the materials break down into simpler compounds without combustion. The result is a variety of byproducts that can be utilized in different ways. For instance, biochar can be used as a soil amendment, improving soil health and sequestering carbon. Syngas can be used for electricity generation or as a fuel for heating, while bio-oil can be further refined into various chemicals or used directly as a fuel source.The environmental benefits of using a pyrolyzer are significant. By converting waste materials into valuable products, this technology helps reduce landfill usage and lowers greenhouse gas emissions. Additionally, the carbon captured in biochar can contribute to carbon negative strategies, helping combat climate change. As society seeks to transition towards more sustainable practices, the role of pyrolyzer technology becomes increasingly critical.Moreover, the versatility of the pyrolyzer allows it to be employed in various industries. For instance, in agriculture, farmers can utilize the biochar produced from their crop residues to enhance soil fertility. In the waste management sector, municipalities can implement pyrolyzer systems to process organic waste, thus generating energy while simultaneously addressing waste disposal issues.Despite its advantages, the adoption of pyrolyzer technology faces challenges. The initial investment costs for setting up a pyrolyzer system can be substantial, which may deter some organizations. Furthermore, there is a need for more research to optimize the pyrolysis process and improve the efficiency of the technology. However, as awareness of sustainability grows and government incentives for clean technologies increase, the future of pyrolyzer applications looks promising.In conclusion, the pyrolyzer represents a forward-thinking solution to some of the pressing environmental challenges we face today. By enabling the conversion of waste into useful products, it holds the potential to transform waste management and energy production. As we continue to innovate and invest in renewable technologies, the pyrolyzer will undoubtedly play a pivotal role in shaping a more sustainable future for our planet.

近年来，可再生能源的重要性变得越来越明显。在这个领域中，出现了一项创新技术，即使用pyrolyzer（热解炉）。pyrolyzer是一种在缺氧的情况下以高温热解有机材料的设备，产生生物炭、合成气和生物油。这个过程被称为热解，它提供了一种可持续的废物管理和能源生产的方法。pyrolyzer的工作原理涉及将生物质、塑料甚至轮胎等有机材料加热到通常在300°C到900°C之间的温度。在此过程中，材料在不燃烧的情况下分解为更简单的化合物。结果是各种副产品，可以以不同的方式利用。例如，生物炭可以用作土壤改良剂，改善土壤健康并固定碳。合成气可以用于发电或作为加热燃料，而生物油可以进一步精炼成各种化学品或直接用作燃料。使用pyrolyzer的环境效益显著。通过将废物转化为有价值的产品，这项技术有助于减少垃圾填埋场的使用并降低温室气体排放。此外，生物炭中捕获的碳可以为负碳策略做出贡献，帮助应对气候变化。随着社会寻求向更可持续的实践过渡，pyrolyzer技术的作用变得越来越重要。此外，pyrolyzer的多功能性使其可以在各个行业中使用。例如，在农业中，农民可以利用从作物残留物中产生的生物炭来提高土壤肥力。在废物管理部门，市政当局可以实施pyrolyzer系统来处理有机废物，从而在解决废物处理问题的同时产生能源。尽管有其优势，pyrolyzer技术的采用面临挑战。建立pyrolyzer系统的初始投资成本可能相当高，这可能会阻碍一些组织。此外，需要更多的研究来优化热解过程并提高技术的效率。然而，随着可持续性意识的提高和政府对清洁技术的激励增加，pyrolyzer应用的未来看起来很有希望。总之，pyrolyzer代表了一种前瞻性的解决方案，可以应对我们今天面临的一些紧迫环境挑战。通过使废物转化为有用产品，它有潜力改变废物管理和能源生产。随着我们继续创新和投资于可再生技术，pyrolyzer无疑将在塑造我们星球更可持续的未来中发挥关键作用。