loading interval

简明释义

装货时间间隔

英英释义

例句

1.The system will start processing data after the loading interval 加载间隔 is completed.

系统将在完成加载间隔 加载间隔后开始处理数据。

2.During the loading interval 加载间隔, users may experience delays in content display.

在加载间隔 加载间隔期间，用户可能会遇到内容显示的延迟。

3.Adjusting the loading interval 加载间隔 can significantly enhance user experience.

调整加载间隔 加载间隔可以显著改善用户体验。

4.To improve performance, we need to optimize the loading interval 加载间隔 of our application.

为了提高性能，我们需要优化应用程序的加载间隔 加载间隔。

5.The application crashed due to a long loading interval 加载间隔 while fetching data.

由于在获取数据时出现了较长的加载间隔 加载间隔，应用程序崩溃了。

作文

In the realm of engineering and technology, particularly in the fields of structural analysis and mechanical systems, the term loading interval holds significant importance. A loading interval refers to the specific duration during which a load is applied to a structure or component. Understanding this concept is crucial for engineers and designers as it directly influences the performance and safety of various structures, from bridges to buildings and even machinery. To illustrate the significance of loading interval, consider the design of a bridge. Engineers must take into account not only the weight of vehicles that will cross the bridge but also how long those loads will be applied. For instance, if a heavy truck drives over the bridge, the loading interval would start when the truck begins to move onto the bridge and end when it has completely crossed. During this time, the bridge experiences stress and strain, and understanding the loading interval helps engineers predict how the materials will respond under such conditions.Moreover, the loading interval can vary significantly depending on the type of load and its movement. Static loads, like the weight of the bridge itself, have a different loading interval compared to dynamic loads, such as moving vehicles or wind forces. Dynamic loads can induce vibrations and fluctuating stresses, making it essential for engineers to accurately define the loading interval to ensure that the structure can withstand these forces without failure.The implications of loading interval extend beyond just structural integrity; they also affect the overall design process. When engineers are aware of the loading interval, they can utilize materials more effectively, optimizing costs while ensuring safety. For example, if the loading interval is short, lighter materials might suffice, whereas a longer loading interval might necessitate stronger, more durable materials to handle the sustained stress.In mechanical systems, the concept of loading interval is equally important. Take, for instance, the operation of a crane. The loading interval defines the timeframe during which the crane lifts a load. If the load is lifted too quickly or held for too long, it may lead to mechanical failures or accidents. Therefore, understanding and managing the loading interval is vital for safe and efficient crane operation.Additionally, the loading interval is a critical factor in fatigue analysis. Materials can fail after repeated loading cycles, and the loading interval plays a pivotal role in determining how long a material can endure such stress before succumbing to fatigue. Engineers must analyze the loading interval to predict the lifespan of components and ensure reliability over time.In conclusion, the term loading interval encapsulates a fundamental aspect of engineering that influences design, safety, and material selection across various applications. By comprehensively understanding and applying the principles surrounding loading interval, engineers can create safer, more efficient structures and systems. This knowledge not only enhances the performance of engineering projects but also contributes to the overall safety and sustainability of infrastructure in our modern world.

在工程和技术领域，特别是在结构分析和机械系统中，术语加载间隔具有重要意义。加载间隔是指施加于结构或组件的负载的特定持续时间。理解这一概念对工程师和设计师至关重要，因为它直接影响到各种结构的性能和安全性，从桥梁到建筑物甚至机械。为了说明加载间隔的重要性，考虑一下桥梁的设计。工程师不仅必须考虑将要通过桥梁的车辆的重量，还必须考虑这些负载将被施加多长时间。例如，如果一辆重型卡车驶过桥梁，加载间隔将在卡车开始驶入桥梁时开始，并在其完全通过时结束。在此期间，桥梁会经历应力和变形，了解加载间隔有助于工程师预测材料在这种条件下的反应。此外，加载间隔可能因负载类型和运动而显著变化。静态负载，如桥梁本身的重量，其加载间隔与动态负载（如移动的车辆或风力）有所不同。动态负载可能引起振动和波动的应力，因此工程师必须准确界定加载间隔，以确保结构能够承受这些力量而不发生故障。加载间隔的影响不仅限于结构完整性；它们还影响整体设计过程。当工程师意识到加载间隔时，他们可以更有效地利用材料，优化成本，同时确保安全性。例如，如果加载间隔较短，则可能只需使用较轻的材料，而较长的加载间隔则可能需要更强、更耐用的材料来承受持续的压力。在机械系统中，加载间隔的概念同样重要。以起重机的操作为例。加载间隔定义了起重机提升负载的时间框架。如果负载提升得太快或保持时间过长，可能会导致机械故障或事故。因此，理解和管理加载间隔对于安全高效的起重机操作至关重要。此外，加载间隔是疲劳分析中的一个关键因素。材料在重复加载周期后可能会失效，而加载间隔在确定材料在屈服前能承受多长时间的压力方面发挥着关键作用。工程师必须分析加载间隔以预测组件的使用寿命，确保长期可靠性。总之，术语加载间隔概括了工程学中的一个基本方面，影响着各种应用中的设计、安全性和材料选择。通过全面理解和应用围绕加载间隔的原则，工程师能够创造出更安全、更高效的结构和系统。这一知识不仅增强了工程项目的性能，还促进了我们现代世界基础设施的整体安全性和可持续性。