infusibility
简明释义
英[ɪnˌfjuːzəˈbɪlətɪ]美[ɪnˌfjʊzəˈbɪləti]
n. [冶] 不熔性(熔点高于1500摄氏度);难溶性
英英释义
The quality of being incapable of being melted or fused, typically referring to certain materials that do not change state when subjected to heat. | 无法熔化或融合的特性,通常指某些材料在加热时不会改变状态。 |
单词用法
高不可熔性 | |
低不可熔性 | |
金属的不可熔性 | |
工程中的不可熔性 |
同义词
| 熔化性 | The fusibility of metals varies greatly depending on their composition. | 金属的熔化性因其成分而异。 | |
| 可熔性 | The meltability of the material is crucial for its application in manufacturing. | 材料的可熔性对其在制造中的应用至关重要。 |
反义词
| 可熔性 | The fusibility of the material allows it to be shaped easily. | 该材料的可熔性使其易于成型。 | |
| 可融化性 | High meltability is essential for processes that require casting. | 高可融化性对需要铸造的工艺至关重要。 |
例句
1.However their infusibility and lack of functional groups have strongly limited the application of CNTs in many fields.
但由于其在很多溶剂中分散性不好且表面缺少官能团限制了其在很多领域的应用。
2.However their infusibility and lack of functional groups have strongly limited the application of CNTs in many fields.
但由于其在很多溶剂中分散性不好且表面缺少官能团限制了其在很多领域的应用。
3.The scientist conducted experiments to test the infusibility of various alloys.
科学家进行了实验,以测试各种合金的耐熔性。
4.The engineer emphasized the importance of the material's infusibility in high-temperature applications.
工程师强调了材料在高温应用中耐熔性的重要性。
5.In the production of ceramics, infusibility is a crucial property that ensures durability.
在陶瓷生产中,耐熔性是确保耐用性的关键特性。
6.Due to its infusibility, the material can withstand extreme environmental conditions.
由于其耐熔性,该材料能够承受极端环境条件。
7.The infusibility of the glass used in the furnace is essential for its longevity.
炉中使用的玻璃的耐熔性对其寿命至关重要。
作文
In the realm of materials science, the concept of infusibility plays a crucial role in determining the applications of various substances. Infusibility refers to the property of a material that prevents it from being fused or melted under heat. This characteristic is particularly significant when selecting materials for high-temperature applications, such as in the aerospace and automotive industries. For instance, ceramics are often chosen for their infusibility, allowing them to withstand extreme temperatures without losing their structural integrity.To better understand the importance of infusibility, consider the example of a spacecraft re-entering the Earth’s atmosphere. The intense heat generated during re-entry can reach thousands of degrees Celsius. Materials used in the heat shield of the spacecraft must exhibit high infusibility to prevent melting and ensure the safety of the crew and equipment inside. Thus, engineers meticulously select materials with this property to enhance the durability and reliability of the spacecraft.Moreover, the infusibility of a material can also influence its thermal conductivity. Generally, materials that are highly infusible tend to have lower thermal conductivity, which makes them excellent insulators. This property is beneficial in applications where heat retention or dissipation is critical, such as in building construction or manufacturing processes. For example, insulating materials like firebricks or certain types of glass wool are valued for their infusibility and ability to resist high temperatures while providing effective insulation.In addition to industrial applications, infusibility can also be observed in everyday materials. Consider the case of cooking utensils made from stainless steel or cast iron. These materials are designed to withstand high cooking temperatures without deforming or melting. Their infusibility ensures that they maintain their shape and functionality over time, making them reliable choices for both professional chefs and home cooks alike.Furthermore, understanding infusibility is essential for recycling efforts. Many materials that are not infusible can release harmful substances when exposed to high temperatures, complicating the recycling process. By focusing on infusibility, manufacturers can develop more sustainable products that are easier to recycle and less harmful to the environment. This shift towards more infusible materials not only promotes sustainability but also encourages innovation in product design and engineering.In conclusion, infusibility is a vital property that influences the selection and application of materials across various industries. Its significance is evident in high-temperature environments, insulation requirements, everyday cooking tools, and sustainable manufacturing practices. As technology continues to advance, the exploration of new materials with enhanced infusibility will undoubtedly lead to improved performance and safety in numerous applications. Understanding and harnessing the power of infusibility will remain a key focus for scientists and engineers alike, driving innovation and progress in material science for years to come.
在材料科学领域,infusibility的概念在确定各种物质的应用中起着关键作用。Infusibility指的是一种材料在加热下无法熔化或融化的特性。这一特性在选择高温应用材料时尤为重要,例如在航空航天和汽车工业中。例如,陶瓷通常因其具有infusibility而被选择,使其能够承受极端温度而不失去结构完整性。为了更好地理解infusibility的重要性,可以考虑一个例子:航天器重新进入地球大气层。再入过程中产生的强烈热量可以达到数千摄氏度。用于航天器热防护罩的材料必须具有高infusibility,以防止融化并确保机组人员和内部设备的安全。因此,工程师们会仔细选择具有这一特性的材料,以增强航天器的耐用性和可靠性。此外,材料的infusibility也可以影响其热导率。通常,高度infusible的材料往往具有较低的热导率,这使它们成为出色的绝缘体。这一特性在建筑施工或制造过程等需要热量保持或散发的应用中非常有利。例如,耐火砖或某些类型的玻璃棉等绝缘材料因其infusibility和抵御高温的能力而受到重视,同时提供有效的绝缘。除了工业应用,infusibility在日常材料中也能观察到。以不锈钢或铸铁制成的烹饪用具为例。这些材料旨在承受高温烹饪而不会变形或融化。它们的infusibility确保了它们在长时间使用中保持形状和功能,使它们成为专业厨师和家庭厨师的可靠选择。此外,理解infusibility对于回收工作至关重要。许多不具备infusibility的材料在高温下可能释放有害物质,从而使回收过程复杂化。通过关注infusibility,制造商可以开发出更可持续的产品,这些产品更易于回收且对环境的危害更小。这种向更多infusible材料的转变不仅促进了可持续发展,还鼓励了产品设计和工程的创新。总之,infusibility是影响各行业材料选择和应用的重要特性。其重要性在高温环境、绝缘要求、日常烹饪工具以及可持续制造实践中显而易见。随着技术的不断进步,对具有增强infusibility的新材料的探索无疑将改善众多应用的性能和安全性。理解和利用infusibility的力量将始终是科学家和工程师的重点,推动材料科学在未来几年的创新和进步。
