ash fusibility

简明释义

煤灰熔融性;

英英释义

例句

1.Understanding ash fusibility is crucial for optimizing the performance of gasifiers.

理解灰熔融性对于优化气化炉的性能至关重要。

2.High ash fusibility can lead to slagging issues in industrial furnaces.

高灰熔融性可能导致工业炉中的结渣问题。

3.We need to assess the ash fusibility of this biomass fuel before using it in our power plant.

在我们的发电厂使用这种生物质燃料之前，我们需要评估其灰熔融性。

4.The ash fusibility test revealed that the coal had a low melting point.

灰熔融性测试显示该煤的熔点较低。

5.The study of ash fusibility helps in determining the combustion efficiency of different coal types.

对灰熔融性的研究有助于确定不同煤种的燃烧效率。

作文

In the field of materials science and engineering, understanding the properties of various substances is crucial for developing efficient processes and products. One such property that has garnered attention is ash fusibility. This term refers to the ability of ash, particularly from biomass or coal, to melt or fuse under high temperatures. The significance of ash fusibility cannot be understated, especially in industries that rely heavily on combustion processes, such as power generation and metallurgy.When materials are burned, they produce ash as a byproduct. The composition of this ash can vary greatly depending on the source material. For instance, wood ash differs significantly from coal ash in terms of chemical makeup and physical characteristics. The ash fusibility of these ashes plays a vital role in determining how they behave during combustion and subsequent handling. If the ash has low fusibility, it may remain in solid form, making it easier to manage. Conversely, if the ash fusibility is high, the ash can melt and create clinkers, which can lead to operational issues such as blockages in boilers or furnaces.Understanding ash fusibility is essential for optimizing combustion efficiency. In power plants, for example, operators must carefully monitor the type of fuel being burned and its corresponding ash characteristics. By selecting fuels with favorable ash fusibility properties, they can minimize the risk of operational disruptions and improve overall efficiency. Additionally, knowledge of ash fusibility aids in the development of new materials that can withstand high-temperature environments without degrading.The testing of ash fusibility typically involves heating samples of ash to determine their melting points and behavior at elevated temperatures. This information is critical for engineers and scientists who are designing systems that involve combustion. Furthermore, the results of these tests can inform decisions regarding fuel selection and combustion technologies, ultimately leading to more sustainable practices.In recent years, there has been an increased focus on renewable energy sources, such as biomass. As the use of biomass for energy continues to rise, understanding the ash fusibility of different types of biomass becomes increasingly important. Different species of plants produce ashes with varying fusibility characteristics, which can impact the efficiency and emissions of biomass combustion. Therefore, research into the ash fusibility of biomass ashes is essential for optimizing their use as a sustainable energy source.In conclusion, ash fusibility is a critical property that influences the behavior of ash produced from combustion processes. Its implications extend across various industries, affecting efficiency, operational reliability, and environmental sustainability. As we continue to explore new energy sources and technologies, understanding ash fusibility will remain a key factor in achieving our goals for cleaner and more efficient energy production.

在材料科学和工程领域，理解各种物质的特性对于开发高效的工艺和产品至关重要。其中一个引起关注的特性是灰熔融性。这个术语指的是灰烬，特别是生物质或煤的灰烬，在高温下熔化或融合的能力。灰熔融性的重要性不容小觑，尤其是在依赖燃烧过程的行业，如发电和冶金。当材料被燃烧时，会产生灰烬作为副产品。这种灰烬的成分可能会因来源材料而有很大差异。例如，木灰与煤灰在化学成分和物理特性上有显著不同。灰熔融性在确定这些灰烬在燃烧及后续处理中的行为方面起着至关重要的作用。如果灰烬的熔融性较低，它可能保持固态，便于管理。相反，如果灰熔融性较高，灰烬可能会熔化并形成结块，导致锅炉或炉子等操作问题，如堵塞。理解灰熔融性对于优化燃烧效率至关重要。在发电厂中，例如，操作员必须仔细监测所燃烧的燃料类型及其相应的灰烬特性。通过选择具有良好灰熔融性特性的燃料，他们可以最大限度地减少操作中断的风险，提高整体效率。此外，了解灰熔融性有助于开发能够在高温环境中耐受而不退化的新材料。灰熔融性的测试通常涉及加热灰烬样本，以确定其熔点和在高温下的行为。这些信息对设计涉及燃烧的系统的工程师和科学家至关重要。此外，这些测试的结果可以为燃料选择和燃烧技术的决策提供依据，最终导致更可持续的实践。近年来，对可再生能源来源（如生物质）的关注有所增加。随着生物质能源使用的不断上升，了解不同类型生物质的灰熔融性变得愈发重要。不同种类的植物产生的灰烬具有不同的熔融特性，这会影响生物质燃烧的效率和排放。因此，研究生物质灰烬的灰熔融性对于优化其作为可持续能源来源的使用至关重要。总之，灰熔融性是影响燃烧过程中产生的灰烬行为的关键特性。其影响遍及各个行业，影响效率、操作可靠性和环境可持续性。随着我们继续探索新的能源来源和技术，理解灰熔融性将始终是实现清洁和高效能源生产目标的关键因素。