rupturing capacity

简明释义

切断功率

英英释义

例句

1.Engineers must consider the rupturing capacity of pipes when designing a water supply system.

工程师在设计供水系统时必须考虑管道的破裂能力。

2.To prevent accidents, it's crucial to understand the rupturing capacity of the materials used.

为了防止事故，了解所用材料的破裂能力至关重要。

3.The rupturing capacity of the balloon is determined by its thickness and material type.

气球的破裂能力由其厚度和材料类型决定。

4.The new material has a high rupturing capacity, making it suitable for extreme conditions.

这种新材料具有很高的破裂能力，使其适合极端条件。

5.The safety tests revealed the rupturing capacity of the container was lower than expected.

安全测试显示容器的破裂能力低于预期。

作文

In the realm of material science and engineering, understanding the properties of materials is crucial for designing structures that can withstand various forces. One important property that engineers often evaluate is the rupturing capacity, which refers to a material's ability to withstand stress before failing or breaking apart. This characteristic is particularly significant in industries such as construction, aerospace, and automotive, where safety and reliability are paramount.The rupturing capacity of a material can be influenced by several factors, including its composition, temperature, and the rate at which stress is applied. For instance, metals generally exhibit high rupturing capacity under tensile stress but may fail under compressive forces if not designed properly. Understanding these nuances allows engineers to select appropriate materials for specific applications, ensuring that structures can endure the stresses they will encounter throughout their lifespan.One of the most notable examples of rupturing capacity in action is seen in the construction of bridges. Engineers must consider the weight of the vehicles that will travel over the bridge and the environmental forces, such as wind and earthquakes, that could affect its stability. By analyzing the rupturing capacity of the materials used in the bridge's construction, they can predict how it will perform under various conditions and make necessary adjustments to enhance its durability.Moreover, advancements in technology have led to the development of new materials with enhanced rupturing capacity. For example, composites and alloys are engineered to combine the benefits of different elements, resulting in materials that are lighter yet stronger than traditional options. This innovation plays a crucial role in industries like aerospace, where reducing weight while maintaining structural integrity is essential for fuel efficiency and overall performance.In addition to practical applications, the concept of rupturing capacity extends beyond physical materials. It can also be applied metaphorically in various fields, such as psychology and sociology. For instance, one might discuss an individual's rupturing capacity in terms of their resilience and ability to cope with stress or adversity. Just as materials can fail under pressure, individuals too have limits to their emotional and mental endurance. Recognizing these limits is vital for fostering well-being and ensuring that people receive the support they need during challenging times.In conclusion, the rupturing capacity of materials is a fundamental concept in engineering that influences the design and safety of structures across multiple industries. By understanding this property, engineers can make informed decisions that enhance the reliability and longevity of their projects. Furthermore, the metaphorical application of rupturing capacity highlights the importance of recognizing human limits in the face of stress, illustrating how interconnected our understanding of strength and resilience can be, both in materials and in life. As we continue to innovate and explore new frontiers, the study of rupturing capacity will remain a critical aspect of both material science and personal development.

在材料科学和工程领域，理解材料的特性对设计能够承受各种力量的结构至关重要。工程师们常常评估的一个重要特性是rupturing capacity，即材料在破裂或断裂之前承受应力的能力。这个特性在建筑、航空航天和汽车等行业尤为重要，因为安全性和可靠性至关重要。材料的rupturing capacity可能受到多种因素的影响，包括其成分、温度以及施加应力的速率。例如，金属在拉伸应力下通常表现出高的rupturing capacity，但如果设计不当，在压缩力下可能会失效。理解这些细微差别使工程师能够选择适合特定应用的材料，从而确保结构能够承受其整个生命周期中遇到的压力。rupturing capacity在实际应用中的一个显著例子可以在桥梁的建造中看到。工程师必须考虑将要通过桥梁的车辆的重量，以及风和地震等环境力量对其稳定性的影响。通过分析用于桥梁建造的材料的rupturing capacity，他们可以预测在各种条件下的表现，并进行必要的调整以增强其耐久性。此外，技术的进步导致了具有增强rupturing capacity的新材料的开发。例如，复合材料和合金被工程化以结合不同元素的优点，结果是比传统选项更轻但更强的材料。这一创新在航空航天等行业中发挥着关键作用，在这些行业中，减轻重量而保持结构完整性对于燃油效率和整体性能至关重要。除了实际应用，rupturing capacity的概念还超越了物理材料。在心理学和社会学等各个领域也可以应用。例如，人们可能会讨论个体的rupturing capacity，即他们应对压力或逆境的韧性和能力。正如材料在压力下可能会失效一样，个人也有其情感和心理耐力的极限。认识到这些极限对促进福祉至关重要，确保人们在困难时期获得所需的支持。总之，材料的rupturing capacity是工程中的一个基本概念，它影响着多个行业结构的设计和安全性。通过理解这一特性，工程师能够做出明智的决策，从而增强项目的可靠性和耐久性。此外，rupturing capacity的隐喻应用突出了在面对压力时认识人类极限的重要性，说明了我们对材料和生活中力量与韧性的理解是如何相互关联的。随着我们继续创新和探索新领域，rupturing capacity的研究将始终是材料科学和个人发展的关键方面。