fusibility

简明释义

英[ˌfjʊsɪˈbɪlɪtɪ]美[ˌfjʊzəˈbɪləti]

n. [物] 熔度；[物] 熔性

英英释义

单词用法

同义词

反义词

例句

1.As a reference, the author emphasized on new technology of determining and the study status to improve the effect of determining the fusibility of coal ash.

重点介绍了新的测定技术及研究现状，为改善煤灰熔融性测定效果提供参考。

2.As a reference, the author emphasized on new technology of determining and the study status to improve the effect of determining the fusibility of coal ash.

重点介绍了新的测定技术及研究现状，为改善煤灰熔融性测定效果提供参考。

3.The Ca-based matter in coal was beneficial to sulfur fixation, and low coal ash fusibility was disadvantage to fixation sulfur.

煤中所含钙基组分对固硫有利，石灰石对低灰熔点煤高温固硫不利。

4.Described the actuality and development of the research of the coal ash fusibility.

描述了国内外对煤灰熔融特性研究的现状和进展。

5.The fusibility of coal ash was different with that of slag.

煤灰与熔渣的熔融特性存在一定差异。

6.The fusibility of metals varies depending on their composition.

金属的熔融性因其成分而异。

7.In the manufacturing process, understanding the fusibility of materials is crucial.

在制造过程中，理解材料的熔融性至关重要。

8.Certain alloys have enhanced fusibility that makes them easier to work with.

某些合金具有增强的熔融性，使其更易于加工。

9.The fusibility of glass can be adjusted by changing its chemical components.

通过改变玻璃的化学成分，可以调整其熔融性。

10.Researchers are studying the fusibility of new composite materials for better performance.

研究人员正在研究新复合材料的熔融性以提高性能。

作文

The concept of fusibility, which refers to the ability of a material to be melted and reshaped, plays a crucial role in various industries, particularly in metallurgy and manufacturing. Understanding fusibility is essential for engineers and scientists who work with different metals and alloys, as it directly affects the processes involved in casting and forging. For instance, metals with high fusibility can be easily melted and molded into complex shapes, making them ideal for creating intricate components in machinery and electronics. In the world of materials science, the fusibility of a substance is determined by its chemical composition and the conditions under which it is heated. Different metals have varying melting points; for example, lead has a low melting point and thus high fusibility, while tungsten has a very high melting point and low fusibility. This variation is significant when selecting materials for specific applications. Engineers must consider the fusibility of materials to ensure that they can withstand the temperatures required for processing without losing their structural integrity. Moreover, the fusibility of materials is not only important for melting but also for recycling processes. In the recycling industry, understanding the fusibility of different metals allows for more efficient separation and processing. For example, aluminum's high fusibility makes it easy to recycle, as it can be melted down and reformed multiple times without degrading its quality. This aspect of fusibility contributes to sustainable practices, reducing waste and energy consumption in manufacturing. In addition to industrial applications, fusibility also has implications in art and design. Artists working with glass or metal often rely on the fusibility of their materials to create unique pieces. The ability to melt and reshape materials enables artists to experiment with form and structure, pushing the boundaries of traditional craftsmanship. For instance, glassblowers utilize the fusibility of glass to create stunning sculptures and functional items, showcasing the beauty of molten materials. Furthermore, advancements in technology have led to new materials with engineered fusibility properties. Researchers are exploring ways to manipulate the fusibility of polymers and composites to develop materials that can change shape or properties under specific conditions. This innovation could lead to breakthroughs in fields such as aerospace, where lightweight and adaptable materials are essential. In conclusion, fusibility is a fundamental property that influences a wide range of applications across various industries. Its importance in metallurgy, recycling, art, and material science cannot be overstated. By understanding and harnessing the principles of fusibility, professionals can create more efficient processes, sustainable practices, and innovative designs. As we continue to explore the potential of materials, the study of fusibility will remain a vital area of research and development, shaping the future of technology and creativity.

“熔化性”这个概念指的是材料被熔化和重塑的能力，在各个行业中起着至关重要的作用，特别是在冶金和制造业。理解“熔化性”对于从事不同金属和合金工作的工程师和科学家来说至关重要，因为它直接影响铸造和锻造中的过程。例如，具有高“熔化性”的金属可以轻松地被熔化并模制成复杂的形状，使其成为制造机械和电子设备中精密部件的理想选择。 在材料科学的世界里，物质的“熔化性”由其化学成分和加热条件决定。不同金属具有不同的熔点；例如，铅的熔点较低，因此“熔化性”较高，而钨的熔点非常高，“熔化性”较低。这种差异在选择特定应用的材料时显得尤为重要。工程师必须考虑材料的“熔化性”，以确保它们能够承受加工所需的温度而不失去结构完整性。 此外，材料的“熔化性”不仅对熔化过程重要，还对回收过程有影响。在回收行业，了解不同金属的“熔化性”可以实现更高效的分离和处理。例如，铝的高“熔化性”使其易于回收，因为它可以被多次熔化和重塑而不降低其质量。“熔化性”的这一方面有助于可持续实践，减少制造中的废物和能源消耗。 除了工业应用外，“熔化性”在艺术和设计中也有重要意义。与玻璃或金属合作的艺术家通常依赖于他们材料的“熔化性”来创造独特的作品。熔化和重塑材料的能力使艺术家能够尝试形式和结构，推动传统工艺的界限。例如，玻璃吹制工匠利用玻璃的“熔化性”创造出令人惊叹的雕塑和功能性物品，展示了熔融材料的美。 此外，技术的进步导致了具有工程“熔化性”特性的材料的出现。研究人员正在探索如何操控聚合物和复合材料的“熔化性”以开发在特定条件下能够改变形状或性质的材料。这一创新可能会在航空航天等领域带来突破，在这些领域，轻巧和适应性强的材料至关重要。 总之，“熔化性”是影响各个行业广泛应用的基本特性。它在冶金、回收、艺术和材料科学中的重要性不容小觑。通过理解和利用“熔化性”的原理，专业人士可以创造更高效的工艺、可持续的实践和创新的设计。随着我们继续探索材料的潜力，“熔化性”的研究将仍然是一个重要的研究和发展领域，塑造技术和创造力的未来。