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Turbulent Flow01:24

Turbulent Flow

795
Turbulent flow is characterized by unpredictable fluctuations in velocity and pressure, which result in a chaotic fluid movement distinct from the orderly patterns of laminar flow. While laminar flow is governed by smooth, parallel layers with minimal mixing, turbulent flow exhibits highly irregular, three-dimensional patterns. This behavior arises due to instabilities in the fluid's velocity profile, and amplifies as the flow velocity increases. Minor disturbances, known as turbulent...
795
Collisions in Multiple Dimensions: Introduction01:05

Collisions in Multiple Dimensions: Introduction

7.1K
It is far more common for collisions to occur in two dimensions; that is, the initial velocity vectors are neither parallel nor antiparallel to each other. Let's see what complications arise from this. The first idea is that momentum is a vector. Like all vectors, it can be expressed as a sum of perpendicular components (usually, though not always, an x-component and a y-component, and a z-component if necessary). Thus, when the statement of conservation of momentum is written for a...
7.1K
Dimensionless Groups in Fluid Mechanics01:15

Dimensionless Groups in Fluid Mechanics

852
Dimensionless groups in fluid mechanics provide simplified ratios that help analyze fluid behavior without relying on specific units. The Reynolds number (Re), which represents the ratio of inertial to viscous forces, distinguishes between laminar and turbulent flows, making it essential in the design of pipelines and aerodynamic surfaces. The Froude number (Fr), the ratio of inertial to gravitational forces, is particularly useful in predicting wave formation and hydraulic jumps in...
852
Turbulent Flow: Problem Solving01:09

Turbulent Flow: Problem Solving

449
Carbonation is a process used to dissolve carbon dioxide gas in a liquid, commonly used in the production of carbonated beverages. Achieving efficient carbonation requires careful control of temperature, pressure, and flow conditions. By adjusting these parameters, carbonation efficiency can be maximized, producing a higher concentration of CO2 in the liquid.
Temperature is a key factor in CO2 solubility. In this case, the CO2 gas and the liquid are cooled to 20°C. Lower temperatures enhance...
449
Collisions in Multiple Dimensions: Problem Solving01:06

Collisions in Multiple Dimensions: Problem Solving

5.6K
In multiple dimensions, the conservation of momentum applies in each direction independently. Hence, to solve collisions in multiple dimensions, we should write down the momentum conservation in each direction separately. To help understand collisions in multiple dimensions, consider an example.
A small car of mass 1,200 kg traveling east at 60 km/h collides at an intersection with a truck of mass 3,000 kg traveling due north at 40 km/h. The two vehicles are locked together. What is the...
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Laminar and Turbulent Flow01:07

Laminar and Turbulent Flow

11.2K
Fluid dynamics is the study of fluids in motion. Velocity vectors are often used to illustrate fluid motion in applications like meteorology. For example, wind—the fluid motion of air in the atmosphere—can be represented by vectors indicating the speed and direction of the wind at any given point on a map. Another method for representing fluid motion is a streamline. A streamline represents the path of a small volume of fluid as it flows. When the flow pattern changes with time, the...
11.2K

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Updated: Feb 24, 2026

Three-dimensional Particle Tracking Velocimetry for Turbulence Applications: Case of a Jet Flow
13:02

Three-dimensional Particle Tracking Velocimetry for Turbulence Applications: Case of a Jet Flow

Published on: February 27, 2016

13.0K

5次元における渦巻のカスケード

José I Cardesa1, Alberto Vela-Martín2, Javier Jiménez2

  • 1School of Aeronautics, Universidad Politécnica de Madrid, 28040 Madrid, Spain. ji.cardesa@upm.es.

Science (New York, N.Y.)
|August 19, 2017
PubMed
まとめ
この要約は機械生成です。

研究者らは 渦巻の流れに 交差するエネルギーの リンクを特定しました 流体エネルギーの塊はより大きなスケールで現れ,より小さなスケールで散らばり,様々な流体タイプの乱流モデリングを改善します.

さらに関連する動画

Simultaneous Measurement of Turbulence and Particle Kinematics Using Flow Imaging Techniques
10:53

Simultaneous Measurement of Turbulence and Particle Kinematics Using Flow Imaging Techniques

Published on: March 12, 2019

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Visually Based Characterization of the Incipient Particle Motion in Regular Substrates: From Laminar to Turbulent Conditions
11:51

Visually Based Characterization of the Incipient Particle Motion in Regular Substrates: From Laminar to Turbulent Conditions

Published on: February 22, 2018

9.2K

関連する実験動画

Last Updated: Feb 24, 2026

Three-dimensional Particle Tracking Velocimetry for Turbulence Applications: Case of a Jet Flow
13:02

Three-dimensional Particle Tracking Velocimetry for Turbulence Applications: Case of a Jet Flow

Published on: February 27, 2016

13.0K
Simultaneous Measurement of Turbulence and Particle Kinematics Using Flow Imaging Techniques
10:53

Simultaneous Measurement of Turbulence and Particle Kinematics Using Flow Imaging Techniques

Published on: March 12, 2019

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Visually Based Characterization of the Incipient Particle Motion in Regular Substrates: From Laminar to Turbulent Conditions
11:51

Visually Based Characterization of the Incipient Particle Motion in Regular Substrates: From Laminar to Turbulent Conditions

Published on: February 22, 2018

9.2K

科学分野:

  • 流体力学
  • トルブルンスの研究
  • 多次元物理学

背景:

  • 渦巻流は様々なスケールで エネルギー散布を示します
  • エネルギーカスケードを理解することは,地質学と産業の流れモデリングに不可欠です.

研究 の 目的:

  • 乱流におけるクロススケールエネルギー転送の統計的優位性を検出し,特徴づけること.
  • 先進的な渦巻モデルを開発するための洞察を提供すること.

主な方法:

  • 異なるスケールでエネルギーを含んだ 流体領域を追跡する
  • スケール間のエネルギー転送の統計的優位性を分析する (Δ,2Δ,Δ/2).

主要な成果:

  • エネルギー転送の主要なクロススケールリンクを特定しました.
  • 観測された液体エネルギー塊は,スケール2Δで現れ,スケールΔで存在し,スケールΔ/2で消散する.
  • 水のような液体の エネルギー・カスケードを証明した

結論:

  • この研究は,乱流のエネルギーカスケードの重要なメカニズムを明らかにしています.
  • 発見は,渦巻モデルを改善するための基本的な洞察を提供します.
  • この方法論は,導電性流体,量子流体,およびプラズマに拡張できます.