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相关概念视频

Steady Flow of a Fluid Stream01:27

Steady Flow of a Fluid Stream

235
Consider a control volume, such as a pipe with solid boundaries, through which fluid flows and changes direction due to the impulse exerted by the resulting force from the pipe walls. In steady flow, the mass of fluid entering the control volume at a given time, t, with velocity v1, is equal to the mass leaving after infinitesimal time dt, with velocity v2.
During this process, the momentum of the fluid within the control volume remains constant over the time interval dt. By applying the...
235
Conservation of Mass in Finite Cotrol Volume01:16

Conservation of Mass in Finite Cotrol Volume

920
The principle of conservation of mass is a fundamental law in fluid mechanics and is applied using the continuity equation. We apply the concept to a finite control volume to derive the continuity equation.
A system is defined as a collection of unchanging contents, and the conservation of mass states that a system's mass is constant.
920
Control Volume and System Representations01:16

Control Volume and System Representations

806
Two key frameworks are employed to analyze mass, energy, and momentum transfer: the control volume approach and the system approach. These frameworks offer different perspectives, depending on whether the focus is on a specific region in space (control volume approach) or a defined mass of fluid (system approach).
The control volume approach considers a stationary region in space through which fluid flows. This region is bounded by a control surface.  For instance, in the case of water...
806
Conservation of Mass in Fixed, Nondeforming Control Volume01:07

Conservation of Mass in Fixed, Nondeforming Control Volume

856
The principle of conservation of mass is fundamental in fluid dynamics and is crucial for analyzing flow within fixed control volumes, such as pipes or ducts. This principle states that the total mass within a control volume remains constant unless altered by the inflow or outflow of mass through the control surfaces. This results in a vital relationship for steady, incompressible flow where the mass entering a system equals the mass leaving it.
In the case of a sewer pipe, which can be modeled...
856
Eulerian and Lagrangian Flow Descriptions01:22

Eulerian and Lagrangian Flow Descriptions

966
Fluid flow analysis is critical in many scientific and engineering disciplines, and two principal approaches are used to describe this flow: the Eulerian and Lagrangian methods. These methods offer different perspectives on monitoring and analyzing the motion of fluids, each with distinct advantages depending on the scenario.
The Eulerian method focuses on fixed points in space where fluid properties, such as velocity, pressure, and temperature, are observed as the fluid moves between these...
966
Introduction to Types of Flows01:23

Introduction to Types of Flows

791
Fluid flows are categorized by dimensionality and behavior, with one-dimensional flow being the simplest form, where properties like velocity and pressure change only along a single axis. Water moving through straight pipes exemplifies this flow type, as variations in other directions are minimal. One-dimensional analysis helps simplify understanding such flows, focusing solely on changes along the pipe's length.
Two-dimensional flow involves changes in both length and height, as seen in...
791

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相关实验视频

Updated: May 27, 2025

Controlling Flow Speeds of Microtubule-Based 3D Active Fluids Using Temperature
08:04

Controlling Flow Speeds of Microtubule-Based 3D Active Fluids Using Temperature

Published on: November 26, 2019

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使用自动分化控制复杂流体的流动行为的控制.

Mohammed G Alhashim1,2, Kaylie Hausknecht3, Michael P Brenner1,3

  • 1School of Engineering and Applied Physics, Harvard University, Cambridge, MA 02138.

Proceedings of the National Academy of Sciences of the United States of America
|February 18, 2025
PubMed
概括
此摘要是机器生成的。

自动分化 (AD) 为解决复杂的流体动力学反向设计问题提供了一种强大而有效的方法. 这种方法简化了高维优化,在各种流体流动场景中证明有效.

关键词:
自动区分的自动区分.混沌的混合混杂.分散的分散性分散.设计的反向设计.优化的优化优化优化.

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Generation and Control of Electrohydrodynamic Flows in Aqueous Electrolyte Solutions
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Analyzing Mixing Inhomogeneity in a Microfluidic Device by Microscale Schlieren Technique
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相关实验视频

Last Updated: May 27, 2025

Controlling Flow Speeds of Microtubule-Based 3D Active Fluids Using Temperature
08:04

Controlling Flow Speeds of Microtubule-Based 3D Active Fluids Using Temperature

Published on: November 26, 2019

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Generation and Control of Electrohydrodynamic Flows in Aqueous Electrolyte Solutions
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Generation and Control of Electrohydrodynamic Flows in Aqueous Electrolyte Solutions

Published on: September 7, 2018

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Analyzing Mixing Inhomogeneity in a Microfluidic Device by Microscale Schlieren Technique
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科学领域:

  • 计算流体动力学 计算流体动力学
  • 优化优化 优化优化
  • 应用数学 应用数学 应用数学

背景情况:

  • 复杂流程的反向设计由于高维优化而在计算上昂贵.
  • 传统方法经常限制控制参数或使用基于附加的方法,这可能是复杂的.
  • 现有的技术在有效处理带有粒子的流量和复杂介质方面面临着挑战.

研究的目的:

  • 证明自动分化 (AD) 是解决复杂流体动力学的反向问题的通用平台.
  • 展示AD的易于实现和计算效率,以实现高维优化.
  • 将AD应用于各种流体流量问题,包括活性物质,多孔介质和期刊轴承.

主要方法:

  • 利用自动差异化 (AD) 的最新进展来进行梯度计算.
  • 应用AD来解决牛顿流体,结构性多孔介质和期刊轴承流的优化问题.
  • 使用AD进行涉及粒子载荷流的高维优化.

主要成果:

  • AD为复杂流体的反向设计问题提供了通用和高效的解决方案.
  • 在多个具有挑战性的流体动力学场景中证明了AD的成功应用.
  • AD显著提高了计算效率,并简化了高维优化的实现.

结论:

  • 自动差异化是解决流体动力学复杂反向设计问题的强大工具.
  • AD方法为传统优化方法提供了更容易获得和更有效的替代方案.
  • 这种方法广泛适用于各种流体流系统,包括具有活性物质和颗粒悬浮的系统.