yield mass distribution

简明释义

产额 质量分布

英英释义

例句

1.The software is capable of simulating processes to yield mass distribution 产生质量分布 profiles.

该软件能够模拟过程以产生质量分布轮廓。

2.We need to analyze how the process conditions affect the yield mass distribution 产生质量分布 in our production line.

我们需要分析工艺条件如何影响生产线中的产生质量分布。

3.The study focused on the factors that could yield mass distribution 产生质量分布 variations in the final product.

研究集中在可能导致最终产品产生质量分布变化的因素上。

4.By adjusting the temperature, we were able to yield mass distribution 产生质量分布 that met our specifications.

通过调整温度，我们能够产生质量分布，符合我们的规格。

5.The experiment was designed to yield mass distribution 产生质量分布 data for the new material.

实验旨在为新材料产生质量分布数据。

作文

In the field of physics and engineering, understanding the concept of yield mass distribution is crucial for analyzing various systems. The term refers to how mass is distributed within an object or system when it reaches its yield point, which is the stage at which materials begin to deform permanently. This phenomenon is particularly important in structural engineering, materials science, and mechanical engineering, as it helps engineers predict how materials will behave under stress, ensuring safety and reliability in design. When a material is subjected to external forces, it initially deforms elastically, meaning it can return to its original shape once the force is removed. However, as the force increases, the material eventually reaches its yield point. At this stage, the distribution of mass within the material becomes critical. The yield mass distribution can affect how the material fails, the formation of cracks, and how the load is transferred through the structure. For instance, consider a steel beam used in construction. When weight is applied to the beam, the mass distribution plays a vital role in determining how much load the beam can support before it yields. A beam with a uniform yield mass distribution will likely perform better under load than one with an uneven distribution, which may lead to localized failures. Engineers must take these factors into account when designing structures to ensure that they can withstand the forces they will encounter during their lifespan.Moreover, the concept of yield mass distribution extends beyond just solid materials. In fluid dynamics, the distribution of mass within a fluid can influence flow patterns and behavior under different conditions. For example, in a pipeline, the way mass is distributed can affect pressure drops and flow rates, impacting the efficiency of the system. Understanding how to manage yield mass distribution in fluids is essential for engineers working in industries such as oil and gas, where precise calculations can lead to significant cost savings and improved safety measures.In conclusion, the understanding of yield mass distribution is fundamental in various fields of science and engineering. It not only helps predict material behavior under stress but also plays a crucial role in the design and analysis of structures and systems. By mastering this concept, engineers can enhance the safety, efficiency, and reliability of their designs, ultimately contributing to advancements in technology and infrastructure. As we continue to innovate and push the boundaries of engineering, the importance of understanding yield mass distribution will only grow, highlighting the need for continued research and education in this vital area.

在物理和工程领域，理解“屈服质量分布”这一概念对于分析各种系统至关重要。该术语指的是当物体或系统达到其屈服点时，质量在其中的分布状态，屈服点是材料开始永久变形的阶段。这一现象在结构工程、材料科学和机械工程中尤为重要，因为它帮助工程师预测材料在应力下的行为，从而确保设计的安全性和可靠性。当材料受到外部力作用时，它最初会发生弹性变形，这意味着一旦去除力，材料可以恢复到原始形状。然而，随着力的增加，材料最终会达到其屈服点。在这个阶段，材料内部的质量分布变得至关重要。屈服质量分布会影响材料的破坏方式、裂缝的形成以及负载在结构中的传递方式。例如，考虑一根用于建筑的钢梁。当重量施加到梁上时，质量分布在决定梁能承受多少负载之前发生屈服方面起着重要作用。具有均匀屈服质量分布的梁在负载下表现可能更好，而具有不均匀分布的梁可能导致局部失效。工程师必须考虑这些因素，以确保结构能够承受其使用寿命内所遇到的力量。此外，“屈服质量分布”的概念不仅仅局限于固体材料。在流体动力学中，流体内部的质量分布可以影响不同条件下的流动模式和行为。例如，在管道中，质量的分布方式会影响压力降和流量，从而影响系统的效率。理解如何管理流体中的屈服质量分布对在石油和天然气等行业工作的工程师至关重要，因为精确的计算可以带来显著的成本节约和改进的安全措施。总之，理解屈服质量分布在科学和工程的各个领域都是基础。它不仅有助于预测材料在应力下的行为，还在结构和系统的设计与分析中发挥着关键作用。通过掌握这一概念，工程师可以提高设计的安全性、效率和可靠性，最终推动技术和基础设施的发展。随着我们继续创新并推动工程的界限，理解屈服质量分布的重要性只会增加，这突显了在这一重要领域继续研究和教育的必要性。