rectangular cross flow

简明释义

垂直交叉流动

英英释义

例句

1.Engineers studied the rectangular cross flow patterns to improve the efficiency of the ventilation system.

工程师研究了矩形横流模式，以提高通风系统的效率。

2.The design of the heat exchanger utilizes a rectangular cross flow configuration to enhance thermal efficiency.

热交换器的设计采用了矩形横流配置，以提高热效率。

3.The rectangular cross flow design in the filtration system allows for better distribution of fluids.

过滤系统中的矩形横流设计允许更好的流体分布。

4.In fluid dynamics, a rectangular cross flow can significantly impact the pressure drop across the system.

在流体动力学中，矩形横流会显著影响系统的压降。

5.The cooling tower was optimized for rectangular cross flow to maximize water evaporation.

冷却塔经过优化，以实现最大化的水蒸发，采用了矩形横流。

作文

Understanding fluid dynamics is crucial in various fields, including engineering, environmental science, and architecture. One of the essential concepts in fluid mechanics is the study of flow patterns, particularly the rectangular cross flow (矩形横流). This term refers to a specific type of fluid movement that occurs when a fluid flows across a rectangular surface or channel, creating unique flow characteristics that can be analyzed and utilized in different applications.In engineering, the concept of rectangular cross flow is often applied in the design of heat exchangers, cooling towers, and ventilation systems. For instance, in a cooling tower, water is distributed over a rectangular area and air flows horizontally across this surface. The interaction between the water and air creates a cooling effect, which is essential for many industrial processes. Understanding how rectangular cross flow operates allows engineers to optimize these systems for efficiency and effectiveness.Moreover, the analysis of rectangular cross flow helps in predicting the behavior of pollutants in waterways. When contaminants are released into a river with a rectangular cross-section, the flow dynamics will determine how quickly and widely these pollutants disperse. Environmental scientists study these patterns to develop strategies for pollution control and remediation. By comprehending the principles of rectangular cross flow, they can better assess the impact of human activities on aquatic ecosystems.In architecture, the concept also plays a significant role, especially in the design of buildings and urban spaces. Architects consider rectangular cross flow when designing ventilation systems to ensure that fresh air circulates effectively throughout a building. By strategically placing windows and vents, architects can create a natural flow of air that enhances indoor comfort while reducing reliance on mechanical heating and cooling systems. This not only contributes to energy efficiency but also promotes a healthier living environment.Furthermore, the study of rectangular cross flow extends to the field of renewable energy. Wind turbines, for example, can be affected by the flow of air across rectangular surfaces. Engineers analyze these flow patterns to maximize energy capture and improve turbine design. By understanding how rectangular cross flow influences wind speed and direction, they can position turbines more effectively to harness wind energy.In conclusion, the concept of rectangular cross flow is integral to various disciplines, from engineering and environmental science to architecture and renewable energy. Its implications are far-reaching, affecting how we design systems, manage resources, and create sustainable environments. As we continue to advance our understanding of fluid dynamics, the importance of studying rectangular cross flow will only grow, highlighting the interconnectedness of our natural and built environments. Through continued research and application, we can leverage the principles of rectangular cross flow to innovate and improve the way we interact with the world around us.

理解流体动力学在工程、环境科学和建筑等多个领域至关重要。流体力学中的一个基本概念是流动模式的研究，特别是矩形横流（rectangular cross flow）。这个术语指的是当流体在矩形表面或通道上流动时发生的一种特定类型的流体运动，产生独特的流动特性，可以在不同应用中进行分析和利用。在工程领域，矩形横流的概念常用于热交换器、冷却塔和通风系统的设计。例如，在冷却塔中，水分布在一个矩形区域上，空气水平流过这个表面。水与空气之间的相互作用产生了冷却效果，这对许多工业过程至关重要。理解矩形横流的运作方式使工程师能够优化这些系统，以提高效率和效果。此外，矩形横流的分析有助于预测污染物在水道中的行为。当污染物被释放到具有矩形截面的河流中时，流动动态将决定这些污染物扩散的速度和范围。环境科学家研究这些模式，以制定污染控制和修复的策略。通过理解矩形横流的原理，他们可以更好地评估人类活动对水生生态系统的影响。在建筑领域，这个概念同样发挥着重要作用，尤其是在建筑和城市空间的设计中。建筑师在设计通风系统时会考虑矩形横流，以确保新鲜空气有效地在建筑物内循环。通过战略性地放置窗户和通风口，建筑师可以创造自然的空气流动，增强室内舒适度，同时减少对机械供暖和制冷系统的依赖。这不仅有助于节能，还促进了更健康的生活环境。此外，矩形横流的研究还扩展到可再生能源领域。例如，风力涡轮机可能受到空气在矩形表面上流动的影响。工程师分析这些流动模式，以最大化能量捕获并改善涡轮机设计。通过理解矩形横流如何影响风速和方向，他们可以更有效地定位涡轮机，以利用风能。总之，矩形横流的概念在工程、环境科学、建筑和可再生能源等多个学科中都是不可或缺的。它的影响深远，影响着我们如何设计系统、管理资源和创造可持续环境。随着我们对流体动力学理解的不断深入，研究矩形横流的重要性只会增加，突显出我们自然环境和人造环境之间的相互联系。通过持续的研究和应用，我们可以利用矩形横流的原理来创新和改善我们与周围世界的互动。