Paul I. Nakayama’s research while affiliated with University of California System and other places

What is this page?

This page lists works of an author who doesn't have a ResearchGate profile or hasn't added the works to their profile yet. It is automatically generated from public (personal) data to further our legitimate goal of comprehensive and accurate scientific recordkeeping. If you are this author and want this page removed, please let us know.

Publications (1)

Turbulence Transport Equations
  • Article

November 1967

·

49 Reads

·

202 Citations

The Physics of Fluids

Francis H. Harlow

·

Paul I. Nakayama

A generalized eddy viscosity function σ, is introduced in order that the Reynolds stress in an incompressible fluid be expressible as a linear combination of the Kronecker and rate‐of‐strain tensors. A transport equation for the eddy viscosity is derived from the general turbulence energy equation, thereby introducing two additional functions, the specific turbulence kinetic energy q, and a scale variable s. To determine the three variables, a transport equation for s is postulated, and a modified Prandtl—Wieghardt relation among the three variables is accepted. The theory is expressed in universal, invariant form, and validity is demonstrated by application to several problems.

Citations (1)

... The k-ε model, which encompasses two transport equations for turbulent kinetic energy kT and its dissipation εΤ, represents a more intricate and widely utilized approach (Harlow, 1967). The k-ε model has demonstrated its ability to offer suitable approximations for various flow types (Rodi, 1980). ...

Reference:

A review on the numerical simulation model of scouring around bridge pier by using Flow-3D software
Turbulence Transport Equations
  • Citing Article

  • November 1967

The Physics of Fluids

Francis H. Harlow

·

Paul I. Nakayama