crush resistance

简明释义

抗破碎性

英英释义

例句

1.The foam used in this mattress provides great crush resistance, ensuring durability over time.

这种床垫中使用的泡沫提供了很好的抗压强度，确保了长期耐用。

2.In the automotive industry, parts are tested for crush resistance to enhance safety in collisions.

在汽车工业中，零件会经过抗压强度测试，以提高碰撞时的安全性。

3.When selecting a container, consider its crush resistance to ensure the contents remain safe during transport.

在选择容器时，请考虑其抗压强度，以确保内容物在运输过程中安全。

4.The construction of the building was designed with high crush resistance to withstand natural disasters.

这座建筑的设计考虑了高抗压强度，以抵御自然灾害。

5.The new packaging material has excellent crush resistance, making it ideal for shipping fragile items.

这种新包装材料具有优异的抗压强度，非常适合运输易碎物品。

作文

Crush resistance is a term often used in engineering and materials science to describe the ability of a material to withstand compressive forces without deforming or breaking. In many applications, particularly in packaging and construction, understanding the crush resistance of materials is crucial for ensuring safety and durability. For example, when designing packaging for fragile items, manufacturers must consider how much pressure the package can handle before it fails. This is where the concept of crush resistance becomes essential. In the world of construction, materials like concrete and steel are chosen not only for their strength but also for their crush resistance. A building that cannot withstand external pressures, such as those from heavy winds or seismic activity, is at risk of collapse. Engineers conduct tests to measure the crush resistance of various materials to ensure that they meet safety standards and can endure the stresses they will face during their lifespan.Moreover, the crush resistance of a material can be influenced by its composition and structure. For instance, composite materials often exhibit higher crush resistance than their individual components due to their unique properties. This makes them ideal for applications requiring lightweight yet strong materials, such as in aerospace and automotive industries. By optimizing the composition of these materials, engineers can enhance their crush resistance, leading to safer and more efficient designs.In everyday life, we encounter crush resistance in various forms. For example, the design of a soda can involves careful consideration of its ability to resist crushing forces. If a can were too weak, it would easily collapse under pressure, leading to spills and waste. Therefore, manufacturers conduct rigorous testing to ensure that their products have adequate crush resistance to withstand handling and transportation.Understanding crush resistance is not just limited to physical materials; it can also extend to other fields such as biology and medicine. For instance, in the study of bones, researchers analyze the crush resistance of bone tissue to understand how it can support weight and resist fractures. This knowledge can inform medical treatments and preventive measures for conditions like osteoporosis, where bone crush resistance is compromised.In conclusion, crush resistance is a vital property that affects a wide range of materials and applications. From packaging and construction to biology and medicine, the ability of a material to resist crushing forces plays a significant role in its functionality and safety. As technology advances, the importance of understanding and improving crush resistance will continue to grow, leading to innovations that enhance the performance and reliability of materials in various industries.

抗压强度是一个经常用于工程和材料科学的术语，描述了材料在不变形或破裂的情况下承受压缩力的能力。在许多应用中，特别是在包装和建筑中，理解材料的抗压强度对于确保安全性和耐用性至关重要。例如，在设计易碎物品的包装时，制造商必须考虑包装在失败之前可以承受多少压力。这就是抗压强度概念变得至关重要的地方。在建筑领域，混凝土和钢材等材料的选择不仅基于其强度，还基于其抗压强度。一座无法承受外部压力（如重风或地震活动）的建筑物面临倒塌的风险。工程师进行测试以测量各种材料的抗压强度，以确保它们符合安全标准，并能够承受其使用寿命内所面临的压力。此外，材料的抗压强度可能会受到其成分和结构的影响。例如，复合材料通常表现出比其单一成分更高的抗压强度，这是由于其独特的性质。这使得它们在航空航天和汽车工业等需要轻质但强大的材料的应用中理想。通过优化这些材料的成分，工程师可以增强其抗压强度，从而导致更安全、更高效的设计。在日常生活中，我们以各种形式遇到抗压强度。例如，苏打罐的设计涉及仔细考虑其抵御压迫力量的能力。如果罐子太弱，它将在压力下轻易崩溃，导致溢出和浪费。因此，制造商进行严格测试，以确保其产品具有足够的抗压强度，以承受处理和运输。理解抗压强度不仅限于物理材料；它也可以扩展到生物学和医学等其他领域。例如，在骨骼研究中，研究人员分析骨组织的抗压强度以了解其如何支撑重量和抵抗骨折。这些知识可以为像骨质疏松症这样的疾病的治疗和预防措施提供信息，其中骨骼的抗压强度受到损害。总之，抗压强度是影响广泛材料和应用的重要属性。从包装和建筑到生物学和医学，材料抵抗压迫力量的能力在其功能性和安全性中起着重要作用。随着技术的发展，理解和改善抗压强度的重要性将继续增长，导致在各个行业中提高材料性能和可靠性的创新。