accelerating creep
简明释义
加速蠕变;
英英释义
Accelerating creep refers to a phenomenon where the deformation of materials, particularly under constant stress, increases over time at an accelerating rate. | 加速蠕变是指在恒定应力下,材料的变形现象随着时间的推移以加速的速度增加。 |
例句
1.The study revealed that the accelerating creep of the glacier could have severe implications for coastal regions.
研究表明,冰川的加速蠕变可能对沿海地区产生严重影响。
2.As the temperature increased, the accelerating creep of the plastic became more pronounced.
随着温度的升高,塑料的加速蠕变变得更加明显。
3.Manufacturers must consider accelerating creep when designing materials for high-temperature applications.
制造商在为高温应用设计材料时,必须考虑加速蠕变。
4.The engineers noticed an increase in the rate of accelerating creep in the bridge's support beams, indicating potential structural issues.
工程师们注意到桥梁支撑梁的加速蠕变速度增加,表明可能存在结构问题。
5.In geotechnical studies, accelerating creep of soil can lead to landslides if not monitored properly.
在岩土工程研究中,土壤的加速蠕变如果没有得到适当监测,可能会导致滑坡。
作文
In recent years, the term accelerating creep has gained attention in various fields, particularly in geology and engineering. This phrase refers to the gradual yet increasing movement of materials or structures over time, often due to factors such as temperature changes, moisture levels, or stress accumulation. Understanding accelerating creep is essential for predicting long-term stability and safety in construction projects, as well as in the study of natural phenomena like landslides and glacier movements.The concept of accelerating creep can be observed in many real-world scenarios. For instance, in a geological context, the slow movement of tectonic plates can lead to significant geological events, such as earthquakes. As stress builds up in the Earth's crust, the rocks may undergo accelerating creep, eventually resulting in a sudden release of energy. This highlights the importance of monitoring such movements to mitigate risks associated with natural disasters.In engineering, accelerating creep is a critical factor in the design and maintenance of structures. Materials like concrete and metals can experience this phenomenon under prolonged stress or high temperatures. For example, bridges and buildings must be designed to accommodate potential accelerating creep to ensure their longevity and safety. Engineers often conduct tests to determine how different materials behave under stress over time, allowing them to make informed decisions during the construction process.Moreover, the implications of accelerating creep extend beyond just physical structures. In the realm of climate change, scientists are increasingly concerned about the accelerating creep of glaciers and ice sheets. As global temperatures rise, these massive ice formations are melting at unprecedented rates, contributing to rising sea levels. The accelerating creep of glaciers not only poses a threat to coastal communities but also disrupts ecosystems and water supplies.To address the challenges posed by accelerating creep, interdisciplinary approaches are necessary. Collaboration between geologists, engineers, and climate scientists can lead to more effective strategies for monitoring and mitigating the effects of this phenomenon. For instance, advanced technologies such as satellite imagery and ground-based sensors can provide real-time data on the movement of glaciers, helping researchers predict future changes and inform policy decisions.In conclusion, the term accelerating creep encapsulates a crucial aspect of both natural and human-made systems. From understanding the slow movements of tectonic plates to ensuring the integrity of our infrastructure, recognizing the implications of accelerating creep is vital for fostering resilience in the face of environmental changes. As we continue to study this phenomenon, it is imperative that we remain vigilant and proactive in our efforts to adapt and respond to the challenges it presents.
近年来,术语加速蠕变在各个领域引起了关注,尤其是在地质学和工程学中。这个短语指的是由于温度变化、湿度水平或应力积累等因素,材料或结构随着时间的推移逐渐但不断增加的运动。理解加速蠕变对于预测建筑项目的长期稳定性和安全性以及研究自然现象(如滑坡和冰川运动)至关重要。加速蠕变的概念可以在许多现实场景中观察到。例如,在地质背景下,构造板块的缓慢运动可能导致重大地质事件,如地震。随着地壳中的应力积累,岩石可能经历加速蠕变,最终导致能量的突然释放。这突显了监测这种运动以减轻自然灾害相关风险的重要性。在工程学中,加速蠕变是设计和维护结构的关键因素。混凝土和金属等材料在长期应力或高温下可能会经历这一现象。例如,桥梁和建筑物必须设计以适应潜在的加速蠕变,以确保其耐久性和安全性。工程师通常进行测试,以确定不同材料在应力下随时间的行为,从而使他们在施工过程中做出明智的决定。此外,加速蠕变的影响不仅限于物理结构。在气候变化领域,科学家们越来越关注冰川和冰盖的加速蠕变。随着全球温度的上升,这些巨大的冰层正在以前所未有的速度融化,导致海平面上升。冰川的加速蠕变不仅对沿海社区构成威胁,还破坏生态系统和水供应。为了解决加速蠕变带来的挑战,需要跨学科的方法。地质学家、工程师和气候科学家之间的合作可以导致更有效的监测和减轻这一现象影响的策略。例如,卫星图像和基于地面的传感器等先进技术可以提供有关冰川运动的实时数据,帮助研究人员预测未来的变化并告知政策决策。总之,术语加速蠕变概括了自然和人造系统中一个关键方面。从理解构造板块的缓慢运动到确保我们基础设施的完整性,认识到加速蠕变的影响对于在环境变化面前培养韧性至关重要。随着我们继续研究这一现象,保持警惕和积极应对其带来的挑战是至关重要的。
相关单词
