actual flux density

简明释义

1. 实际通量密度; 2. 有效磁感应;

英英释义

例句

1.The actual flux density in the core of the inductor was found to exceed the safe operating limits.

发现电感器核心中的实际通量密度超过了安全工作限制。

2.In solar energy systems, the actual flux density of sunlight can vary significantly depending on the time of day.

在太阳能系统中，阳光的实际通量密度会根据一天中的时间显著变化。

3.Researchers are studying the actual flux density of electric fields in various materials for better insulation.

研究人员正在研究各种材料中电场的实际通量密度以改善绝缘性能。

4.The engineer measured the actual flux density in the magnetic field to ensure it met the design specifications.

工程师测量了磁场中的实际通量密度以确保其符合设计规范。

5.To optimize the performance of the transformer, we need to calculate the actual flux density under different load conditions.

为了优化变压器的性能，我们需要在不同负载条件下计算实际通量密度。

作文

In the realm of physics and engineering, the concept of actual flux density plays a crucial role in understanding various phenomena related to fields and forces. To grasp this term fully, it is essential to break it down into its components: 'flux' and 'density.' Flux refers to the flow of a physical quantity through a surface, while density indicates how much of that quantity exists per unit area. Therefore, actual flux density can be defined as the measure of the amount of flux passing through a specific area at a given moment in time.Understanding actual flux density is vital in several applications, including electromagnetism, fluid dynamics, and even environmental science. For instance, in electromagnetism, actual flux density relates to the electric or magnetic field strength in a particular region. It helps engineers design efficient electrical systems by calculating how much energy is transmitted through a given area.In practical terms, consider a scenario where engineers are tasked with designing a new power transmission line. They must calculate the actual flux density of the electromagnetic field around the line to ensure that it operates safely and efficiently without interfering with nearby structures or causing harm to living organisms. This calculation involves considering various factors such as the current flowing through the wires and the distance from the lines to the surrounding environment.Moreover, actual flux density also finds relevance in meteorology and environmental studies. For example, when measuring air pollution levels, scientists often look at the actual flux density of pollutants emitted from industrial sources. By understanding how much pollutant is released per unit area, they can assess the impact on air quality and public health. This information is crucial for developing regulations and policies aimed at reducing emissions and protecting the environment.In addition to its applications, the concept of actual flux density is also significant in theoretical studies. Researchers often use it to model complex systems and predict how changes in one component can affect the entire system. For instance, in climate modeling, scientists may analyze the actual flux density of greenhouse gases in the atmosphere to understand their contribution to global warming. By studying these patterns, they can develop more accurate models to predict future climate scenarios and inform policy decisions.Furthermore, the importance of actual flux density extends beyond scientific research and engineering; it also has implications in everyday life. For example, understanding the actual flux density of sunlight hitting a solar panel helps in optimizing its placement and orientation for maximum energy capture. This knowledge allows homeowners and businesses to make informed decisions about renewable energy investments, ultimately contributing to a more sustainable future.In conclusion, the term actual flux density encapsulates a fundamental concept that bridges various disciplines, from physics and engineering to environmental science and daily life. By understanding and applying this concept, we can enhance our ability to analyze, design, and optimize systems that rely on the flow of physical quantities. Whether it is ensuring the safe operation of electrical systems, assessing environmental impacts, or harnessing renewable energy, the significance of actual flux density cannot be overstated. As we continue to face challenges related to energy consumption and environmental sustainability, a deep comprehension of such concepts will be essential for progress and innovation in our society.

在物理和工程领域，实际通量密度的概念在理解与场和力相关的各种现象中起着至关重要的作用。要充分掌握这个术语，有必要将其分解为两个组成部分：'通量'和'密度'。通量是指通过表面流动的物理量，而密度则表示每单位面积存在多少该物理量。因此，实际通量密度可以定义为在特定区域内某一时刻通过的通量量的测量。理解实际通量密度在多个应用中至关重要，包括电磁学、流体动力学甚至环境科学。例如，在电磁学中，实际通量密度与特定区域内的电场或磁场强度有关。它帮助工程师通过计算在给定区域内传输的能量量来设计高效的电气系统。在实际操作中，考虑一个工程师被要求设计新的电力传输线路的场景。他们必须计算电线周围电磁场的实际通量密度，以确保其安全高效地运行，不干扰附近的建筑物或对生物造成伤害。这个计算涉及考虑多种因素，例如流经电线的电流以及电线与周围环境之间的距离。此外，实际通量密度在气象学和环境研究中也具有相关性。例如，当测量空气污染水平时，科学家通常会查看工业源排放的污染物的实际通量密度。通过了解每单位面积释放的污染物数量，他们可以评估对空气质量和公众健康的影响。这些信息对于制定旨在减少排放和保护环境的法规和政策至关重要。除了其应用外，实际通量密度的概念在理论研究中也很重要。研究人员经常使用它来建模复杂系统并预测一个组成部分的变化如何影响整个系统。例如，在气候建模中，科学家可能会分析大气中温室气体的实际通量密度，以了解它们对全球变暖的贡献。通过研究这些模式，他们可以开发更准确的模型来预测未来气候情景，并为政策决策提供信息。此外，实际通量密度的重要性超越了科学研究和工程；它在日常生活中也有影响。例如，了解阳光照射到太阳能电池板上的实际通量密度有助于优化其位置和方向，以最大化能源捕获。这一知识使得房主和企业能够就可再生能源投资做出明智的决策，从而最终促进更可持续的未来。总之，术语实际通量密度概括了一种基本概念，连接了多个学科，从物理学和工程学到环境科学和日常生活。通过理解和应用这一概念，我们可以增强分析、设计和优化依赖于物理量流动的系统的能力。无论是确保电气系统的安全运行、评估环境影响还是利用可再生能源，实际通量密度的重要性都不容小觑。随着我们继续面临与能源消耗和环境可持续性相关的挑战，对这些概念的深入理解将对我们社会的进步和创新至关重要。