An Investigation of MEMS-Based Transducers for Boundary Layer Control

Abstract

Using direct numerical simulations of turbulent channel flow, we present new insight into the generation of streamwise vortices near the wall, and an associated drag reduction strategy. Growth of x-dependent spanwise velocity disturbances w(x) is shown to occur via two mechanisms: (1) linear transient growth, which dominates early-time evolution, and (2) linear normal-mode instability, dominant asymptotically at late time (for frozen base flow streaks). Approximately 25% of streaks extracted from near-wall turbulence are shown to be strong enough for linear instability (above a critical vortex line Lift angle!. However, due to viscous annihilation of streak normal vorticity, normal mode growth ceases after a factor of two energy growth. In contrast, the linear transient disturbance produces a 20-fold amplification, due to its rapid, early-time growth before significant viscous streak decay. Thus, linear transient growth of w(x) is revealed as a new, apparently dominant, generation mechanism of x-dependent turbulent energy near the wall.

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Document Details

Document Type
Technical Report
Publication Date
Dec 21, 2000
Accession Number
ADA385633

Entities

People

  • Sudeep M. Kumar
  • Thomas W. Kenny
  • William C. Reynolds

Organizations

  • Stanford University

Tags

Communities of Interest

  • Advanced Electronics
  • Energy and Power Technologies
  • Sensors

DTIC Thesaurus Topics

  • Boundary Layer
  • Ceramic Materials
  • Chemical Vapor Deposition
  • Computational Fluid Dynamics
  • Construction
  • Control Systems
  • Fabrication
  • Flow Visualization
  • Fluid Dynamics
  • Fluid Flow
  • Fluid Mechanics
  • Heat Transfer
  • Manufacturing
  • Measurement
  • Mechanics
  • Microelectromechanical Systems
  • Micromachining

Fields of Study

  • Physics

Readers

  • Fluid Mechanics and Fluid Dynamics.
  • Plasma Physics / Magnetohydrodynamics