centrifugal measurement

简明释义

离心测量;

英英释义

例句

1.The researcher explained how centrifugal measurement can be applied in the field of biochemistry.

研究人员解释了如何将离心测量应用于生物化学领域。

2.The lab technician used centrifugal measurement to determine the density of the liquid sample.

实验室技术员使用离心测量来确定液体样本的密度。

3.In the quality control process, centrifugal measurement is essential for assessing the separation efficiency.

在质量控制过程中，离心测量对于评估分离效率至关重要。

4.The results from the centrifugal measurement indicated a significant difference in particle size distribution.

来自离心测量的结果表明颗粒大小分布存在显著差异。

5.Using centrifugal measurement, we can accurately analyze the components of the mixture.

通过使用离心测量，我们可以准确分析混合物的成分。

作文

In the realm of physics and engineering, the concept of centrifugal measurement plays a pivotal role in understanding how forces interact with objects in motion. This term refers to the technique used to measure the effects of centrifugal force, which is the apparent force that draws a rotating body away from the center of rotation. In simpler terms, when an object spins, it experiences a force that pushes it outward, away from the axis of rotation. This phenomenon is not only fascinating but also essential in various applications, from amusement park rides to industrial machinery.One of the most common examples of centrifugal measurement can be seen in centrifuges, devices that spin samples at high speeds to separate substances based on density. In a laboratory setting, scientists use centrifuges to isolate blood components, such as plasma and red blood cells, for analysis. The centrifugal measurement in this case helps determine how effectively the centrifuge separates these components, ensuring accurate results in medical diagnostics.Moreover, centrifugal measurement is crucial in the design of various mechanical systems, including turbines and engines. Engineers must account for the centrifugal forces acting on moving parts to ensure stability and functionality. For instance, in a jet engine, the spinning blades generate significant centrifugal force that must be measured and managed to prevent mechanical failure. This illustrates how centrifugal measurement is not merely an academic concept but a practical necessity in engineering disciplines.In addition to its applications in science and engineering, centrifugal measurement also has implications in everyday life. Consider the experience of riding a roller coaster. As the ride spins and loops, riders feel a force pushing them against their seats. This sensation is a direct result of centrifugal measurement, as the ride's design must account for the forces exerted on passengers to ensure safety and comfort. Understanding these forces enhances the overall experience, making rides thrilling yet secure.Furthermore, the principles behind centrifugal measurement extend to the field of meteorology. Weather patterns, such as cyclones and tornadoes, are influenced by rotational forces. Meteorologists utilize centrifugal measurement to predict storm behavior and intensity, which is vital for issuing warnings and preparing communities for severe weather events. By analyzing the centrifugal forces at play, scientists can better understand the dynamics of these powerful natural phenomena.In conclusion, centrifugal measurement is a fundamental concept that intersects various fields, including physics, engineering, medicine, and meteorology. Its applications range from laboratory experiments to the design of complex machinery and even the thrill of amusement park rides. By measuring the effects of centrifugal force, we gain insights that enhance our understanding of motion and stability in both natural and artificial systems. As technology continues to advance, the importance of centrifugal measurement will undoubtedly grow, paving the way for innovations that rely on our ability to harness and manipulate these forces effectively.

在物理和工程领域，离心测量的概念在理解力与物体运动之间的相互作用方面发挥着关键作用。这个术语指的是用于测量离心力影响的技术，离心力是将旋转物体从旋转中心拉开的表观力。简单来说，当一个物体旋转时，它会经历一种将其向外推开的力量。这种现象不仅令人着迷，而且在各种应用中至关重要，从游乐园的游乐设施到工业机械。离心测量最常见的例子可以在离心机中看到，这是一种以高速旋转样品的设备，根据密度分离物质。在实验室环境中，科学家使用离心机来分离血液成分，如血浆和红细胞，以进行分析。在这种情况下，离心测量有助于确定离心机分离这些成分的有效性，确保医学诊断中的准确结果。此外，离心测量在各种机械系统的设计中也至关重要，包括涡轮机和发动机。工程师必须考虑作用于运动部件的离心力，以确保稳定性和功能。例如，在喷气发动机中，旋转的叶片产生显著的离心力，必须进行测量和管理，以防止机械故障。这说明了离心测量不仅仅是一个学术概念，而是工程学科中的实际必要性。除了在科学和工程中的应用外，离心测量在日常生活中也有影响。考虑一下乘坐过山车的体验。当游乐设施旋转和循环时，乘客会感到一种将他们推向座椅的力量。这种感觉直接源于离心测量，因为游乐设施的设计必须考虑施加在乘客身上的力量，以确保安全和舒适。理解这些力量增强了整体体验，使游乐设施既刺激又安全。此外，离心测量背后的原理扩展到气象学领域。天气模式，如气旋和龙卷风，受到旋转力的影响。气象学家利用离心测量来预测风暴的行为和强度，这对发布警报和准备社区应对严重天气事件至关重要。通过分析作用于自然现象的离心力，科学家能够更好地理解这些强大自然现象的动力学。总之，离心测量是一个基本概念，交叉涉及多个领域，包括物理学、工程学、医学和气象学。它的应用范围从实验室实验到复杂机械的设计，甚至包括游乐园游乐设施的刺激体验。通过测量离心力的影响，我们获得的见解增强了我们对自然和人工系统中运动和稳定性的理解。随着技术的不断进步，离心测量的重要性无疑将增长，为依赖于我们有效利用和操控这些力量的创新铺平道路。