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Courses on Turbulence

Table of Contents

• 1. Lecture
  • 1.1. UIUC Renewable energy and turbulent environment group
  • 1.2. Turbulent Flow and Transport: MIT open course
    • 1.2.1. reading lists

1 Lecture

DEN403, QMUL

1.1 UIUC Renewable energy and turbulent environment group

TAM

Theoretical and appl Mechanics

http://catalog.illinois.edu/courses-of-instruction/tam/

http://chamorro.mechse.illinois.edu/teaching.htm ME 310: Fundamentals of Fluid Dynamics

Introduction to fluid mechanics with coverage of theory and applications of incompressible viscous and inviscid flows, and compressible high-speed flows. 4 undergraduate hours. TAM 538: Turbulence

Instability and origins of chaotic motion in fluid flow; Reynolds averaging and statistical description of turbulence, correlations and spectral dynamics of homogeneous turbulence, anisotropic flows, coherent structures, inhomogeneous turbulence, transport models, and large-eddy simulations. Prerequisite: TAM 532. 4 graduate hours. (http://mechanical.illinois.edu/courses/tam-538-turbulence) TAM 532: Viscous Flow

Dynamics of flow in which viscosity is significant or dominant, and the development and use of theoretical and numerical tools for practitioners of modern fluid mechanics; physics of viscous layers that arise in both high- and low-Reynolds-number flows; dimensional analysis, exact solutions to the Navier-Stokes equations; jets and wakes; microhydrodynamics; fluid stability; and an introduction to turbulence. Prerequisite: TAM 435 or equivalent; MATH 380; MATH 385, MATH 386, or MATH 441. 4 graduate hours (http://mechanical.illinois.edu/courses/tam-532-viscous-flow) TAM 537: Experimental Fluid Mechanics

Methods and techniques for measurement and analysis of data used in experimental fluid mechanics: signal processing, electronics, and electro-optics; fluid mechanical properties; experimental signal processing; random data and signal analysis; analog and digital data processing; dynamic similarity, self-preservation; pressure measurement, thermal anemometry, and laser-Doppler velocimetry; flow visualization, particle-image velocimetry. Lecture/lab format. Prerequisite: TAM 531 or TAM 532. 4 graduate hours. (http://mechanical.illinois.edu/courses/tam-537-experimental-fluid-mechanics) ME 470: Senior Design Project

Students are required to solve an actual, real-world design problem; to develop, evaluate, and recommend alternative solutions; and to satisfy realistic constraints that include most of the following considerations: economic; environmental; sustainability; manufacturability; ethical; health and safety; social; and political. Prerequisite: Senior standing in Mechanical Engineering; completion of or concurrent enrollment in all required courses; completion of campus Composition I general education requirement. 3 undergraduate hours.

(http://mechanical.illinois.edu/courses/me-470-senior-design-project) ME 597: Independent Study

Independent study of advanced problems related to mechanical engineering. May be repeated in the same term or in separate terms if topics vary to a maximum of 12 hours. Prerequisite: Consent of instructor.

(http://mechanical.illinois.edu/courses/me-597-independent-study)

1.2 Turbulent Flow and Transport: MIT open course

California Environmental Resource Evaluation Service.)

Instructor(s) Prof. Ain Sonin

1.2.1 reading lists

Sonin. Fundamental Laws of Motion: Particles, Material Volumes, And Control Volumes.

Sonin. The Equation of Motion for Viscous Fluids.

White. Viscous Fluid Flow. 2nd ed. 1991, pp. 59-89, 96-100.

Pope. Chap. 2; or other books.

Class notes plus summaries handed out by Sonin

Handout: Sonin. "The Thermodynamic Constitutive Equations and the Equation for Temperature."

Class notes

Bird, Curtis, and Hirschfelder. Molecular Theory of Gases and Liquid. 1954, pp. 8-16.

Vincenti & Kruger. Introduction to Physical Gas Dynamics.1965, pp.15-20. 2 3 Pope. Chap. 3 and 4. Sec. 3.3 Tennekes & Lumley. Chap. 1 and 2, pp. 19-24. Sec. 3.5-3.7 White. 2nd ed., pp. 402-409. Sec. 3.8

Schlichting. 7th ed., pp. 578-586.

White. pp. 436-440. 4

For Laminar Flow:

White. 2nd ed., pp. 253-260, 301-304, 470-481.

Pope. Chap. 4 & 5.

Schlichting. 7th ed. Chap. 24, pp.183-185.

For Turbulent Shear Layer:

Champagne, Pao, and Wygnaski. J. Fluid Mech., 74 (1976), pp. 209-250.

Further Reading:

Hinze. Chap. 6.

Abramovich. The Theory of Turbulent Jets. pp. 103-113, 120-125.

Rajaratnam. "Turbulent Jets." Elsevier, 1976.

Rodi. Studies in Convection. Edited by B. E. Launder. Academic Press, 1975, pp. 79 ff.

Townsend. Chap. 6 in The Structure of Turbulent Shear Flow. 2nd ed. Cambridge, 1976.

Handouts:

Selected experimental data and summaries. 5 Sec. 7.1-.7.2, 10.1-10.2

Pope.

White. 2nd ed., pp. 411-416, 421-429, 436-440.

Schlichting. Chap. 19 & 20. Sec. 5.2- 5.5

Monin & Yaglom I. Chap. 3.

Tennekes & Lumley. pp. 147-165, 171-176. 6

Pope. pp. 298 ff.

White. pp. 409-421, 429-.443.

Schlichting. Chap. 21.

Bradshaw. Chap. 2.

Cebeci & Smith. Analysis of Turbulent Boundary Layers. Academic, 1974. Sec. 6.7

Bushnell & McGinley. "Turbulence control in wall flows." Ann. Rev. Fluid Mech. Vol. 21 (1989), pp.1.

Hinze. 681-84.

Blackwelder & Haritonidis. J. Fluid Mech., 132 (1983), pp. 87-103.

Walsh & Lindemann. AIAA.84.0347.

Gallagher & Thomas. AIAA.84.2185.

Bechert. AIAA.85.0546. 7

Morton, Taylor & Turner. Proc. Roy. Soc. A, 234 (1956), pp. 1-23.

Turner. Buoyancy Effects in Fluids. Cambridge, 1973, pp. 165-173, 194-200.

Chen & Rodi. "A Review of Experimental Data." Vertical Turbulent Buoyant Jets. Pergamon Press, 1980.

Fay. "Buoyant Plumes and Wakes." Ann. Rev. Fluid Mech., Vol. 5 (1973).

List. "Turbulent Jets and Plumes." Ann. Rev. Fluid Mech., Vol. 14 (1982).

Rodi. Turbulent Buoyant Jets & Plumes. Pergamon Press, 1982. 8

Pope. Chap. 4, 10, 11.

Chen & Yaw. Fundamentals of Turbulence Modeling. Taylor & Francis, 1998.

Libby. Introduction to Turbulence. Taylor& Francis, 1996.

LaJones, and under. Int. J. Heat Mass Transfer, 15 (1972): 301.

LaJones, and under. Int. J. Heat Mass Transfer, 16 (1973): 1119.

Bradshaw, Cebeci, and Whitelaw. Engineering Calculation Methods for Turbulent Flow. Academic Press, 1981.

Rodi. Turbulence models and their applications in Hydraulics– "a state of the art review," Int. Assoc. for Hydraulics.

Research, Delft, 1984.

Rodi. Engineering Turbulence Modelling and Experiments 3, Elsevier (1996).

Turbulence. Chap. 1 & 5. Edited by Bradshaw. Springer, 1978.

Monin & Yaglom. Vol. 1. MIT Press, 1979, pp. 373-393, 393 ff. 9

Taylor, G. I. Proc. Roy. Soc. A: 219 (1953), pp. 186-203 (Laminar); 223 (1954), pp. 446-468, (Turbulent); 225 (1954), pp. 473-477.

Proc. Phys. Soc. 67, 12.B (1955), pp. 857-869.

Aris. R. Proc. Roy. Soc. A. 235 (1956), pp. 67-77.

Probstein, R. F. Physicochemical Hydrodynamics. 2nd ed. Wiley, 1994, pp. 87, 93.

Monin & Yaglom, Statistical Fluid Mechanics. Vol. 1. MIT, 1973, pp. 617-627.

Levich, Physicochemical Hydrodynamics, Prentice Hall, 1962, pp. 116-120.

Fischer, H. B. "Longitudinal dispersion and turbulent mixing in open channel flow." Ann. Rev. Fluid Mech., Vol. 5 (1973), pp. 59-78.

Chatwin, P. C., and P. J. Sullivan. J. Fluid Mech., 120 (1982), pp. 347-358.

Smith, R. J. Fluid Mech., 215 (1990), pp. 195-207.

Author: kaiming

Created: 2019-06-01 Sat 09:19

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