infusible

简明释义

英[ɪnˈfjuːzəb(ə)l]美[ɪnˈfjuːzəbl]

adj. 不熔化的；不熔化性的

英英释义

单词用法

同义词

反义词

例句

1.The results show that the main compositions of the infusible matters are zinc oxide and the part of copper oxide that are brought in the process of casting.

分析结果表明，不熔物主要成分是氧化锌及部分氧化铜，主要是在熔铸时抽心夹入。

2.The results show that the main compositions of the infusible matters are zinc oxide and the part of copper oxide that are brought in the process of casting.

分析结果表明，不熔物主要成分是氧化锌及部分氧化铜，主要是在熔铸时抽心夹入。

3.The batch mixes for floor bricks were synthesized on the basis of fusible clay, infusible clay and fluxes.

以易熔粘土为基，并引入难熔粘土和熔剂成分，合成了地砖坯料。

4.When selecting materials for aerospace applications, engineers prefer infusible substances to ensure safety.

在选择航空航天应用的材料时，工程师更喜欢难熔的物质以确保安全。

5.The material used in this high-temperature furnace is highly infusible, making it suitable for extreme conditions.

用于这个高温炉的材料是高度难熔的，使其适合极端条件。

6.The infusible nature of some metals makes them ideal for use in high-performance engines.

某些金属的难熔性使它们非常适合用于高性能发动机。

7.Glass can be infusible when heated to certain temperatures, retaining its shape and integrity.

当加热到某些温度时，玻璃可以是难熔的，保持其形状和完整性。

8.Certain ceramics are known for their infusible properties, allowing them to withstand high heat without melting.

某些陶瓷因其难熔的特性而闻名，使其能够承受高温而不熔化。

作文

Infusible materials play a crucial role in various fields, particularly in engineering and materials science. The term infusible refers to substances that cannot be melted or fused when subjected to heat. This property makes them invaluable in applications where high temperatures are involved. For instance, ceramics and certain metals exhibit infusible characteristics, allowing them to maintain their structural integrity even under extreme conditions. Understanding the nature of infusible materials can aid engineers in selecting the right components for high-temperature environments, such as in aerospace or nuclear industries.In everyday life, we encounter infusible materials more often than we realize. For example, the tiles used in the construction of ovens and furnaces are typically made from infusible ceramics. These materials are designed to withstand intense heat without melting, ensuring safety and durability. Similarly, the refractory bricks lining industrial kilns are infusible, allowing them to endure the harsh conditions of metal smelting processes.The significance of infusible materials extends beyond industrial applications. In the realm of art, glassblowers utilize infusible substances to create stunning works of art that can withstand both heat and time. The intricate designs crafted from infusible glass demonstrate not only the aesthetic qualities of these materials but also their practical advantages.Moreover, the study of infusible materials contributes to advancements in technology. As researchers explore new compounds and mixtures, they aim to develop infusible materials that can perform even better under demanding conditions. Innovations in this field can lead to more efficient energy systems, improved insulation, and enhanced safety measures in various industries.In conclusion, the term infusible describes materials that resist melting and offer exceptional durability under heat. Their applications are diverse, ranging from industrial uses to artistic creations. As we continue to innovate and discover new infusible materials, we pave the way for advancements that will shape the future of technology and engineering. Understanding the properties and potential of infusible substances is essential for anyone involved in scientific research or practical applications in high-temperature environments.

不可熔化的材料在各个领域中发挥着至关重要的作用，尤其是在工程和材料科学中。术语不可熔化的指的是在加热时无法熔化或融合的物质。这一特性使它们在高温环境中应用时显得尤为宝贵。例如，陶瓷和某些金属表现出不可熔化的特性，使它们即使在极端条件下也能保持结构完整性。理解不可熔化的材料的性质可以帮助工程师选择适合高温环境的正确组件，例如在航空航天或核工业中。在日常生活中，我们比想象中更常遇到不可熔化的材料。例如，用于建造烤箱和熔炉的瓷砖通常由不可熔化的陶瓷制成。这些材料设计用于承受强烈的热量而不融化，从而确保安全和耐用性。同样，衬砌工业窑炉的耐火砖是不可熔化的，使它们能够忍受金属冶炼过程中的恶劣条件。不可熔化的材料的重要性超越了工业应用。在艺术领域，吹玻璃工匠利用不可熔化的物质创作出可以抵御热量和时间的惊人艺术品。用不可熔化的玻璃制作的精美设计不仅展示了这些材料的美学特性，还展现了它们的实用优势。此外，对不可熔化的材料的研究有助于技术的进步。随着研究人员探索新的化合物和混合物，他们旨在开发出在苛刻条件下表现更好的不可熔化的材料。该领域的创新可以导致更高效的能源系统、改进的绝缘材料和增强的各种行业的安全措施。总之，术语不可熔化的描述了在热量下抵抗熔化并在高温下提供卓越耐久性的材料。它们的应用范围广泛，从工业用途到艺术创作。随着我们继续创新和发现新的不可熔化的材料，我们为将塑造未来技术和工程的进步铺平了道路。理解不可熔化的物质的特性和潜力对于任何参与高温环境中的科学研究或实际应用的人来说都是至关重要的。