nonlocalized damage

简明释义

不能确定地点的损坏

英英释义

例句

1.After the storm, the building showed signs of nonlocalized damage 非局部损伤 that affected multiple areas but was not easily visible.

暴风雨过后，建筑物显示出非局部损伤 nonlocalized damage的迹象，影响了多个区域，但不易察觉。

2.The technician explained that the device suffered from nonlocalized damage 非局部损伤, making it difficult to pinpoint the exact cause of failure.

技术人员解释说，该设备遭受了非局部损伤 nonlocalized damage，这使得很难确定故障的确切原因。

3.In medical imaging, nonlocalized damage 非局部损伤 can indicate systemic issues rather than localized injuries.

在医学成像中，非局部损伤 nonlocalized damage可能表明系统性问题，而不是局部损伤。

4.The analysis revealed nonlocalized damage 非局部损伤 to the infrastructure, suggesting widespread deterioration over time.

分析显示基础设施存在非局部损伤 nonlocalized damage，表明随着时间的推移，普遍恶化。

5.The car's engine experienced nonlocalized damage 非局部损伤, leading to a series of performance issues that were hard to diagnose.

汽车的发动机经历了非局部损伤 nonlocalized damage，导致一系列性能问题，难以诊断。

作文

In the realm of engineering and materials science, the concept of nonlocalized damage is crucial for understanding how structures respond to various stresses and failures. Unlike localized damage, which occurs in a specific area and can often be identified and repaired, nonlocalized damage refers to damage that is spread out over a larger area or is not easily identifiable. This type of damage poses significant challenges for engineers and designers as it may not be immediately apparent until catastrophic failure occurs.One of the primary concerns with nonlocalized damage is that it can lead to a gradual degradation of material properties without any visible signs. For instance, in composite materials used in aerospace applications, microscopic cracks may develop throughout the material rather than in one concentrated area. These cracks can compromise the integrity of the entire component, making it essential to monitor the health of the structure continuously.The implications of nonlocalized damage extend beyond just engineering; they are also relevant in fields such as medicine and environmental science. In medicine, for example, nonlocalized damage can refer to conditions like systemic inflammation, where damage occurs throughout the body rather than in one specific location. Understanding this concept is vital for developing effective treatment strategies that address the root causes of illness rather than just the symptoms.In environmental science, nonlocalized damage can be observed in ecosystems where pollutants affect large areas rather than isolated spots. This widespread impact can lead to long-term ecological consequences that are difficult to reverse. By recognizing the patterns and effects of nonlocalized damage, scientists can better strategize conservation efforts and pollution control measures.To effectively manage nonlocalized damage, it is essential to employ advanced monitoring techniques and predictive models. Non-destructive testing methods, such as ultrasonic testing and thermography, can help identify hidden flaws within materials before they lead to significant failure. Additionally, the use of sensors embedded within structures can provide real-time data on the health of a system, allowing for timely maintenance and intervention.Furthermore, education and awareness about nonlocalized damage are crucial for professionals across various fields. By understanding the nature of this type of damage, engineers, medical practitioners, and environmental scientists can collaborate more effectively to mitigate risks and enhance safety. Workshops, seminars, and interdisciplinary research initiatives can foster a deeper understanding of how nonlocalized damage affects their respective fields, ultimately leading to better solutions and innovations.In conclusion, nonlocalized damage represents a complex challenge that spans multiple disciplines. Its subtlety and widespread nature require a proactive approach to detection and management. By investing in research, technology, and education, we can better equip ourselves to deal with the implications of nonlocalized damage and ensure the safety and longevity of our structures, health, and environment.

在工程和材料科学领域，非局部损伤的概念对于理解结构如何应对各种应力和故障至关重要。与发生在特定区域并且通常可以识别和修复的局部损伤不同，非局部损伤是指分布在更大区域或不易识别的损伤。这种类型的损伤给工程师和设计师带来了重大挑战，因为它可能不会立即显现，直到发生灾难性故障。非局部损伤的主要问题之一是，它可能导致材料性能的逐渐退化，而没有任何明显的迹象。例如，在航空航天应用中使用的复合材料中，微观裂纹可能在材料中发展，而不是集中在一个地方。这些裂纹可能会影响整个组件的完整性，因此持续监测结构的健康状况至关重要。非局部损伤的影响不仅限于工程；在医学和环境科学等领域也相关。在医学中，例如，非局部损伤可以指全身性炎症等情况，其中损伤发生在整个身体而不是一个特定位置。理解这一概念对于制定有效的治疗策略至关重要，这些策略针对疾病的根本原因，而不仅仅是症状。在环境科学中，非局部损伤可以在生态系统中观察到，污染物影响大面积而不是孤立的点。这种广泛的影响可能导致长期的生态后果，难以逆转。通过识别非局部损伤的模式和影响，科学家可以更好地制定保护措施和污染控制措施。为了有效管理非局部损伤，必须采用先进的监测技术和预测模型。无损检测方法，如超声波检测和热成像，可以帮助在重大故障发生之前识别材料中的隐患。此外，嵌入结构中的传感器可以提供关于系统健康状况的实时数据，从而允许及时的维护和干预。此外，提高对非局部损伤的认识和教育对于各个领域的专业人士至关重要。通过理解这种类型的损伤的性质，工程师、医疗从业者和环境科学家可以更有效地合作，以减轻风险并提高安全性。研讨会、讲座和跨学科研究倡议可以促进对非局部损伤如何影响各自领域的更深入理解，最终导致更好的解决方案和创新。总之，非局部损伤代表了跨多个学科的复杂挑战。其微妙性和广泛性需要采取主动的方法进行检测和管理。通过投资于研究、技术和教育，我们可以更好地装备自己，以应对非局部损伤的影响，并确保我们结构、健康和环境的安全与持久性。