Peter M. Moretti
Publications & Citations

Moretti's home-page is at moretti.ceat.okstate.edu

Textbooks

Peter M. Moretti, Modern Vibrations Primer, © 2000, CRC Press, Boca Raton, FL 33431, ISBN 0-8493-2038-0 (available on amazon.com).

Supplementary Instructors' Manual: Peter M. Moretti, Solutions Manual for Modern Vibrations Primer, CRC Press, Boca Raton, FL 33431, © 2000, ISBN 0-8493-1150-0 - available to Professors from CRC Press, http:/www.crcpress.com/

Reviewed by R.G. Parker, Book Review 9R4, Appl. Mech. Rev. vol. 53, no. 9 (Sept. 2000), pp. B87f.

Reviewed in MEbookshelf, Mechanical Engineering, vol. 123, no. 2 (Feb. 2001), ASME, New York, p. 70.

Web Handling

P.M. Moretti, “Flag Flutter Amplitudes,” Flow Induced Vibration, de Langre & Axisa ed., Ecole Polytechnique, Paris, 6-9 July 2004, vol. I, pages 113-118.

Peter M. Moretti, “Lateral Deflections of Webs in Air-Flotation Ovens,” Trans. ASME, Journal of Applied Mechanics, vol. 71, no. 3 (May 2004), pp. 314-320.

Peter M. Moretti, “Tension in Fluttering Flags,” International Journal of Acoustics and Vibration, vol. 8, no. 4 (December 2003), ISSN 1027-5851, pp. 227-230; originally presented in Proceedings of the Tenth International Congress on Sound and Vibration, July 7-10, 2003, Stockholm, Sweden, pages 2123-2130 (see also final equations in corrected manuscript).

P.M. Moretti, “Tension in Fluttering Flags,” printed Abstract and oral presentation at 23rd Oklahoma AIAA/ASME Symposium, March 8, 2003, University of Oklahoma, Norman.

Y.B. Chang & P.M. Moretti, “Flow-induced vibration of free edges of thin films,” Journal of Fluids and Structures, Vol.16, No. 7 (Oct. 2002), pp. 989-1008; doi:10.1006/jfls.2002.0456 available online at IDEAL and www.sciencedirect.com

Cited by Merrill Vaughan & Arvind Raman, “Aeroelastic Stability of Axially Moving Webs Coupled to Incompressible Flows”, ASME, Journal of Applied Mechanics, 2004.

Peter M. Moretti, “Flutter in Webs,” Seminar, T.U. Darmstadt (Germany), October 28, 2002, and also in Kaiserslautern, October 31, 2002.

P.M. Moretti, “Lateral Deflections of Webs in Air-Flotation Ovens,” Proceedings of the Sixth International Conference on Web Handling, ed. J.K. Good, Web Handling Research Center, Oklahoma State University, Stillwater, Oklahoma, June 11-13, 2001, pp 531-546.

P.M. Moretti, invited “Conference Report FIV2000” (including Book Review), Journal of Fluids and Structures (Academic Press), vol. 15, No. 2 (Feb. 2001), no. 2, pp. 371-372; online at IDEAL www.idealibrary.com or www.sciencedirect.com

Y.B. Chang & P.M. Moretti, “Flow-induced vibration of free edges of thin films,” Proceedings of the 7th International Conference on Flow-Induced Vibrations - FIV2000, Lucerne, Switzerland, June 19-21, 2000, ed. S. Ziada & T. Staubli, publ. A.A. Balkema, Rotterdam, Netherlands, ISBN 90-5809-129-5, pp. 801-810.

Y.B. Chang & P.M. Moretti, “Aerodynamic Characteristics of Pressure-Pad Air Bars,” Trans. ASME, J. Applied Mechanics, vol. 67, no. 1 (March 2000), pp. 177-182.

Peter M. Moretti, “Threadlines,” Section 28.8 in Modern Vibrations Primer, CRC Press, Boca Raton, FL 33431, © 2000, ISBN 0-8493-2038-0, pp. 302f.

Young B. Chang, Ronald P. Swanson, & Peter M. Moretti, “Longitudinal and Out-of-Plane Stiffness of a Web in an Air-Flotation Oven,” ASME, Noise Control and Acoustics Division - 1999, NCA-Vol. 26, Nashville, Tennessee, Nov. 14-19, 1999, ASBN 0-7198-1637-0, pp. 435-443.

Young B. Chang, Chang H. Cho, & Peter M. Moretti, “Edge Flutter,” Proc. ASME, Noise Control and Acoustics Division - 1999, NCA-Vol.26, Nashville, Tennessee, Nov. 14-19, 1999, ASBN 0-7198-1637-0, pp. 413-423.

Cited by Merrill Vaughan & Arvind Raman, “Aeroelastic Stability of Axially Moving Webs Coupled to Incompressible Flows”, ASME, Journal of Applied Mechanics, 2004.

Y.B. Chang, R. Swanson, & P.M. Moretti, “Resiliency of an Air-Floated Web,” Proc. of the Fifth International Conference on Web Handling, ed. J.K. Good, Stillwater, Oklahoma, June 6-9, 1999, ISBN 0-9654616-2-9, pp. 543-559.

V.R. Aravamudhan, P.M. Moretti, & Y.B. Chang, “An Experimental Study of the Coanda Effect for 90-Degree Turning of Subsonic Air Jets,” ASME Fluids Engineering Conference, Summer 1998, Washington, D.C.

Y.B. Chang & P.M. Moretti, “Aerodynamic Characteristics of Pressure-Pad Air Bars,” ASME Aerospace Div. 4th International Symposium on Fluid-Structure Interactions, Aeroelasticity, Flow-Induced Vibration and Noise, Proc. 1997 ASME Int. Mech. Engrg. Congress, Part 2, vol. 53-2, Dallas, Texas, Nov. 17-21, 1997, ISSN 0733-4230, pp. 3-9.

P.M. Moretti & Y.B. Chang, “Web Flutter at Circular-Tube Air-Turn Bars,” Proc. Fourth International Conference on Web Handling, ed. J.K. Good, Stillwater, Oklahoma, June 1-4, 1997, ISBN 0-9654616-1-0, pp. 496-511.

P.M. Moretti & Y.B. Chang, “Coupling between Out-of-Plane Displacement and Lateral Stability of Webs in Air-Support Ovens,” Proc. Third International Conference on Webhandling, ed. J.K. Good, Stillwater, Oklahoma, June 18-21, 1995, ISBN 0-9654616-0-2, pp. 338-347.

Y.B. Chang & P.M. Moretti, “Ground-Effect Theory and its Application to Air-Flotation Devices,” Proc. Third International Conference on Webhandling, ed. J.K. Good, Stillwater, Oklahoma, June 18-21, 1995, ISBN 0-9654616-0-2, pp. 348-365.

Peter M. Moretti, Young-Bae Chang, & Krishna Vedula, “Vibration intensity measurement of fluttering webs by laser-Doppler sensors,” Proceedings of SPIE (Int. Soc. for Optical Engrg.), vol. 2358, (First Int. Conf. on Vibration Measurements by Laser Techniques: Advances and Applications, Ancona, Italy, Oct. 3, 1994), ASBN: 0-8194-1697-5, pp. 409-420.

Y.B. Chang, C.H. Cho, & P.M. Moretti, “Edge Flutter of Translating Webs induced by Cross-Flow of Air,” Proc. Third International Conference on Air- and Structure-Borne Sound and Vibration, Montreal, Canada, June 13-15, 1994, pp. 1127-1134.

Y.B. Chang & P.M. Moretti, “An Experimental Study on Edge Flutter in Webs,” Web Handling - 1992, ed. J.K. Good, AMD-Vol. 149, pp. 67-78, American Society of Mechanical Engineers, N.Y. 1992, ASBN 0-7918-1104-2; also presented at ASME Winter Annual Meeting, Anaheim, Calif., Nov. 11, 1992.

Cited by Merrill Vaughan & Arvind Raman, “Aeroelastic Stability of Axially Moving Webs Coupled to Incompressible Flows”, ASME, Journal of Applied Mechanics, 2004.

Y.B. Chang, S.J. Fox, D.G. Lilley, & P.M. Moretti, “Aerodynamics of Moving Belts, Tapes, and Webs,” ASME , Machinery Dynamics and Element Vibrations, DE-Vol. 36, ed. T.C. Huang et al., American Society of Mechanical Engineers, N.Y. 1991, ASBN 0-7918-0627-8, pp. 33-40; also presented at ASME Thirteenth Biennial Conference on Mechanical Vibration and Noise, Symposium on Dynamics of Axially Moving Continua, Miami, Florida, Sept. 22-25, 1991.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

Y.B. Chang & P.M. Moretti, “Edge Flutter in Webs,” Proc. First International Conference on Web Handling, ed. J.K. Good, Stillwater, Oklahoma, May 19-22, 1991, ISBN 0-935269-12-6, pp. 257-289.

Young Bae Chang & Peter M. Moretti, “Interaction of Fluttering Webs with Surrounding Air,” TAPPI Proceedings, 1990 Engineering Conference, Book 1, pp. 175-182, Seattle, Washington, Sept. 24-27, 1990; revised and reprinted in TAPPI Journal, vol. 74, no. 3, pp. 231-236, 1991.

Cited by Y.B. Chang, S.J. Fox, D.G. Lilley, & P.M. Moretti, “Aerodynamics of Moving Belts, Tapes, and Webs,” ASME, Machinery Dynamics and Element Vibrations, DE-Vol. 36, ed. T.C. Huang et al., pp. 33-40, ASME, N.Y. 1991.

Flow-Induced Vibrations in Heat Exchangers

Peter M. Moretti, “Flow Induced Vibrations and Flow Instabilities,” Chapter 42 in Modern Vibrations Primer, CRC Press, Boca Raton, FL 33431, ©2000, ISBN 0-8493-2038-0.

P.M. Moretti, “Why can the prediction of heat-exchanger vibrations fail?” invited presentation, HTRI Horizons Symposium, Feb. 16, 1998, Houston, Texas.

Reviewed in The Exchanger, Issue 6.1, Heat Transfer Research Inc., College Station, Texas, online at http://www.htri-net.com/Newsletters/Exch61/EX61horizons.html

Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993, ISSN: 0066-4189, CODEN: ARVFA3. [OSU Library call number 532.508 A615]

Cited by V. Kassera & K. Strohmeier, “Vibration-Proof Design of Tube Bundles in Heat-Exchangers” (in German), Chemie Ingenieur Technik, v. 67 (1995), n. 2, pp. 188-189.

Cited by U. Boldes & J. Colman, “About some Aspects of the Wake Flow of a small Cypress Tree, in a Free-Stream with a Power-Law Mean Velocity Distribution,” J. Wind Engineering and Industrial Aerodynamics, V. 61 (1996), n. 1, pp. 25-50.

Cited by J. Mizushima & Y. Takemoto, “Stability of the Flow past a Row of Square Bars,” J. Physical Society of Japan, v. 65 (1996), n. 6, pp. 1673-1685.

Cited by H.R. Barsamian & Y.A. Hassan, “Large-Eddy Simulation of Turbulent Cross-Flow in Tube Bundles,” Nuclear Engineering and Design, v. 172 (1997), n. 1-2, pp. 103-122.

Cited by J.W. Hoyt & R.H.J. Sellin, “Flow over Tube Banks - A Visualization Study,” Trans. ASME, J. Fluids Engineering, v. 119 (1997), n. 2, pp. 480-483.

Cited by S. Umeda & W.J. Yang, “Interaction of von Kårmån vortices and intersecting main streams in staggered tube bundles,” Experiments in Fluids, v. 26, n. 5 (April 1999), pp. 389-396.

Cited by Y.A. Hassan & H.R. Barsamian, “Turbulence simulation in tube bundle geometries using the dynamic subgrid-scale model,” Nuclear Technology, v. 128, n.1 (Oct. 1999), pp. 58-74.

Cited by J. Mizushima & Y. Kawaguchi, “Transition of flow past a row of square bars,” J. of Fluid Mechanics, v. 405 (Feb. 25, 2000), pp. 305-323.

Cited by Y. Zhou, R.M.C. So, M.H. Liu, & H.J. Zhang, “Complex turbulent wakes generated by two and three side-by-side cylinders,” Int. J. of Heat and Fluid Flow, v. 21, n. 2 (April 2000), pp. 125-133.

Cited by H.J. Zhang & Y. Zhou. “Effect of unequal cylinder spacing on vortex streets behing three side-by-side cylinders,” Phys. Fluids, v. 13, n. 12, (Dec. 2001), pp. 3675-3686.

M. Cheng & P.M. Moretti, “Lock-In of Vortex Shedding from a Normal Pair of Cylinders with Forced Transverse Vibration,” 1992 International Symposium on Flow-Induced Vibration and Noise, Volume 6: Bluff-Body/Fluid and Hydraulic Machine Interactions, FED-Vol.138/PVP-Vol.245, pp. 25-37, American Society of Mechanical Engineers, N.Y. 1992, ASBN 0-7918-1083-6; also presented at ASME Winter Annual Meeting, Anaheim, Calif., Nov. 11, 1992.

M. Cheng & P.M. Moretti, “Lock-In Phenomena on a Single Cylinder with Forced Transverse Vibration,” Flow-Induced Vibration and Wear - 1991, PVP-Vol. 206, ed. M. K. Au-Yang and F. Hara, pp. 129-133, 1991; also presented at Pressure Vessel and Piping Conference, Symposium on Flow-Induced Vibration, San Diego, Calif., June 23-27, 1991.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

Cited by O.M. Griffith & M.S. Hall, “Vortex-shedding lock-in in a circular-cylinder wake,” pp. 3-14 in Flow-Induced Vibration: Proc. Int. Conf. Flow-Induced Vibration, London, U.K., 10-12 April 1995, ed. P.W. Bearman, publ. Balkema, Rotterdam, ISBN 90-5410-547-X, cited on pages. 5, 6, 8, 9, & 10.

M. Cheng & P.M. Moretti, “Flow Instabilities in Tube Bundles,” Symposium Volume Flow-Induced Vibrations - 1989, PVP-Vol. 154, ASME, Honolulu, July 23-27, 1989, ISSN 0277-027X, pp. 11-15.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

M. Cheng & P.M. Moretti, “Experimental Study of the Flow Field Downstream of a Single Tube Row,” Experimental Thermal and Fluid Science (International Journal of Experimental Heat Transfer Thermodynamics, and Fluid Mechanics, Elsevier Science Publ.), vol. 1, no. 1, pp. 69-74, January 1988.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

Cited by D. Sumner, S.S.T. Wong, S.J. Price, & M.P. Païdoussis, “Fluid behaviour of side-by-side circular cylinders in steady cross-flow,” J. of Fluids and Structures, v. 13, n. 3 (Apr. 1999), pp. 309-338.

Cited by Y. Zhou, R.M.C. So, M.H. Liu, & H.J. Zhang, “Complex Turbulent wakes generated by two and three side-by-side cylinders,” Int. J. of Heat and Fluid Flow, v. 21, n. 2 (April 2000), pp. 125-133.

P.M. Moretti & M. Cheng, “Instability of Flow Through Tube Rows,” Trans. ASME, J. Fluids Engineering, vol. 109, no. 2, pp. 197-198, June 1987.

Cited by M.M. Zdravkovich & K.L. Stonebanks, “Intrinsically Non-Uniform and Metastable Flow in and Behind Tube Arrays,” 1988 International Symposium on Flow-Induced Vibration and Noise, Volume 1 (Chicago, November 29, 1988), American Society of Mechanical Engineers, 345 East 47th Street, New York, N.Y. 10017, ASME Publication G00441.

Cited by M.J. Braun, V.A. Canacci, & L.M. Russell, “Full-Field Flow-Visualization and Computer-Aided Velocity-Measurements in a Bank of Cylinders in a Wind-Tunnel,” Exp. Fluid, v. 13 (1992), n. 2-3, pp. 117-127.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

Cited by M.J. Braun & V.V. Kudriavtsev, “Fluid-Flow Structures in Staggered Banks of Cylinders located in a Channel,” J. Fluids Engineering, v. 117 (1995), n. 1, pp. 36-44.

Cited by J. Mizushima & Y. Takemoto, “Stability of the Flow past a Row of Square Bars,” J. Physical Society of Japan, v. 65 (1996), n. 6, pp. 1673-1685.

Cited by D. Sumner, S.S.T. Wong, S.J. Price, & M.P. Païdoussis, “Fluid behaviour of side-by-side circular cylinders in steady cross-flow,” J. of Fluids and Structures, v. 13, n. 3 (Apr. 1999), pp. 309-338.

Cited by D.W. Guillaume & J.C. LaRue, “Investigation of the flopping regime with two-, three-, and four-cylinder arrays,” Experiments in Fluids, v. 27, n. 2 (July 1999), pp. 145-156.

Cited by J. Mizushima & Y. Kawaguchi, “Transition of flow past a row of square bars,” J. of Fluid Mechanics, v. 405 (Feb. 25, 2000), pp. 305-323.

Peter M. Moretti, “Caught in a Cross Flow - The Paradox of Flow-Induced Vibrations,” Mechanical Engineering, vol. 108, no. 12, pp. 56-61, American Society of Mechanical Engineers, New York, December 1986; see also correction in vol. 109, no. 2, p. 2, February 1987.

Excerpted in textbook by Arthur P. Fraas, Heat Exchanger Design, Second Edition, Wiley-Interscience, New York 1989, on pages 192, 193, & 198.

Cited by P.M. Moretti & M. Cheng, “Instability of Flow Through Tube Rows,” J. Fluid Eng., vol. 109, no. 2, pp. 197f, 1987.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

P.M. Moretti, “Fundamental Frequencies of U-Tubes in Tube Bundles,” Trans. ASME, J. Pressure Vessel Technology, vol. 107, no. 2, pp. 207-209, May 1985.

Cited by C.D. Nieh (Q.-D. Nie) & M.X. Zhang, “Natural Frequencies of Exchanger U-Tubes,” Hydrocarbon Process., vol. 70, no. 5, pp. 97-100, 1991.

D.C. Nguyen, T. Lester, J.K. Good, R.L. Lowery, & P.M. Moretti, “Lowest Natural Frequencies of Multiple Supported U-Tubes,” Trans. ASME, J. Pressure Vessel Technology, vol. 106, no. 4, pp. 414-416, Nov. 1984.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

P.M. Moretti, “Heat-Exchanger Vibration: Experience with Vibration at a Duct-Mounted Heat Exchanger,” Inst. Diagnostic Engrs., Jan./Feb. 1984.

P.M. Moretti, “Fundamental Frequencies of U-Tubes in Tube Bundles,” Symposium Volume Vibration in Power Plant Piping and Equipment, American Society of Mechanical Engineers, Denver, June 24, 1981, pp. 1-4.

Cited by D.C. Nguyen, et al., “Lowest Natural Frequency of Multiply Supported U-Tubes,” Trans. ASME, J. Press. Vess. Tech., vol. 106, no. 4, pp. 414-416, 1984.

R.L. Lowery & P.M. Moretti, “Natural Frequencies and Damping of Tubes on Multiple Supports,” Heat Transfer, Research and Application, ed. J. C. Chen, AIChE Symposium Series No. 174, Vol. 74, 1978, pp. 1-5.

Excerpted in textbook by K.P. Singh & A.I. Soler, Mechanical Design of Heat Exchangers and Pressure Vessel Components, Arcturus Publ., Cherry Hill, N.J., 1984 - on pages 786, 787, & 838.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

P.M. Moretti, “Problem Areas and Needed Research in Heat-Exchanger Tube Vibrations,” in Flow-Induced Tube Vibrations in Shell-and-Tube Heat Exchangers, ed. J. M. Chenoweth for ERDA, SAN/1273-1, UC-93, pp. A35 to A37, February 1977.

P.M. Moretti & R.L. Lowery, “Hydrodynamic Inertia Coefficients for a Tube Surrounded by Rigid Tubes,” Trans. ASME, J. of Pressure Vessel Technology, vol. 98, series J, no. 3, pp. 190-193, August 1976.

Excerpted in textbook by Robert D. Blevins, Flow-Induced Vibrations (First Edition), Van Nostrand Reinhold, New York 1977 (reprinted by Krieger Publ., Malabar, Florida) - in Fig. 5-5 and on pages 94 & 117.

Excerpted in textbook by Robert D. Blevins, Formulas for Natural Frequency and Mode Shape, Van Nostrand-Reinhold, New York, 1979 (reprinted by Krieger Publ., Malabar, Florida in 1984) - on pages 399 & 423.

Excerpted in textbook by Robert D. Blevins, Flow-Induced Vibration - Second Edition, Van Nostrand Reinhold, New York 1990 - on pages 215 & 237.

Cited by S.S. Chen, “Vibration of Nuclear Fuel Bundles,” Nucl. Eng. De., vol. 35, no. 3, pp. 399-422, 1975.

Cited by H. Chung & S.S. Chen, “Vibration of a Group of Circular-Cylinders in a Confined Fluid“, J. Appl. Mech., vol. 44, no. 2, pp. 213-217, 1977.

Cited by B.T. Lubin, K.H. Haslinge, A. Puri, & J. Goldberg, “Frequency Response of a Tube Bundle in Water,” J. Fluid Eng., vol. 99, no. 2, pp. 416-418, 1977.

Cited by R.G. Dong, “Size Effect in Damping Caused by Water Submersion,” J. Struct. Di., vol. 105, pp. 847-857, 1979.

Cited by W.H. Lin & S.S. Chen, “On the Added Mass and Radiation Damping of Rod Bundles Oscillating in Compressible Fluids,” J. Sound Vib., vol. 74, no. 3, pp. 441-453, 1981.

Cited by P.M. Moretti, “Fundamental Frequencies of U-Tubes in Tube Bundles,” J. Press. Vess., vol. 107, no. 2, pp. 207-209, 1985.

Cited by C.C. Chiu, “Influence of Air and Material Damping on Dynamic Elastic-Modulus Measurement,” J. Mater. Sci., vol. 26, no. 18, p. 4910-4916, 1991.

Cited by D. Mewes & D. Stockmeier, “Fluid viscosity effects on flow-induced vibrations of tubes in cross-flow,” Proceedings of the Institution of Mechanical Engineers, Flow Induced Vibration, pp. 231-237, 1991.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

Cited by J.L. Parrondo, C. Santolaria, & D.S. Weaver, “The effect of partial admission on the fluidelastic instability of a parallel triangular tube-array subject to water cross-flow,” Flow-Induced Vibration: Proc. Int. Conf. Flow-Induced Vibration, London, U.K., 10-12 April 1995, ed. P.W. Bearman, publ. Balkema, Rotterdam, ISBN 90-5410-547-X, pp.315-326.

Cited by Y.R. Yang & J.Y. Zhang, “Frequency Analysis of a Parallel Flat Plate-Type Structure in Still Water,” J. Sound and Vibration, v. 203 (1997), n. 5, pp. 795-804.

Cited by J.K. Sinha & R.I.K. Moorthy, “Added mass of submerged perforated tubes,” Nuclear Engineering and Design, v. 193, n. 1-2 (Sept. 1999), pp. 23-31.

P.M. Moretti & R.L. Lowery, “Hydrodynamic Inertia Coefficients for a Tube Surrounded by Rigid Tubes,” invited paper, ASME Pressure Vessel and Piping National Congress, ASME Paper 75-PVP-47, San Francisco, June 23, 1975, 5 pages.

P.M. Moretti, R.L. Lowery, & J.G. Withers, “Structural Characteristics of Helical-Corrugated Heat-Exchanger Tubes,” ASME Paper No. 75-WA/HT-14, Winter Annual Meeting of the American Society of Mechanical Engineers, Houston, Texas, December 1, 1975, 4 pages.

Cited by P.M. Moretti, “Fundamental Frequencies of U-Tubes in Tube Bundles,” J. Press. Vess., vol. 107, no. 2, pp. 207-209, 1985.

Cited by T.J. Rabas & J. Taborek, “Performance, fouling and cost considerations of enhanced tubes in power-plant condensers,” J. Enhanced Heat Transfer, v. 6 (1999), n. 2-4, pp. 289-315 (also cites 1975 report, ERME11, Okla. State Univ.).

P.M. Moretti & R.L. Lowery, “Corrugated Tube Vibration Study” Final Report ER 75-ME-11 to Wolverine Tube Div. of Universal Oil Products, March 1975, Oklahoma State University Library, Special Collections, Call Number 621.4025 M845c.

R.L. Lowery & P.M. Moretti, “Natural Frequencies and Damping of Tubes on Multiple Supports,” invited paper, ASME/AIChE 15th National Heat Transfer Conference, AIChE Paper No. 1, San Francisco, August 11, 1975.

Excerpted in textbook by K.P. Singh & A.I. Soler, Mechanical Design of Heat Exchangers and Pressure Vessel Components, Arcturus Publ., Cherry Hill, N.J., 1984 - on pages 786, 787, and 838.

Cited by G.W. Schwarz, “Preventing Vibration in Shell-and-Tube Heat Exchangers,” J. Chem. Eng., vol. 83, no. 15, pp. 134-140, 1976.

P.M. Moretti, “A Critical Review of the Literature and Research on Flow-Induced Vibrations in Heat Exchangers,” Heat transfer-research and design, ed. D. Gidaspow, AIChE Symposium, series 138, vol. 70, pp. 185-189, 1974.

Cited by M.P. Païdoussis, “Fluid-Elastic Vibration of Cylinder Arrays in Axial and Cross Flow-State of the Art,” J. Sound Vib., vol. 76, no. 3, pp. 329-360, 1981.

Cited by P.M. Moretti, “Fundamental Frequencies of U-Tubes in Tube Bundles,” J. Press. Vess., vol. 107, no. 2, pp. 207-209, 1985.

Cited by Peter M. Moretti, “Flow-Induced Vibrations in Arrays of Cylinders,” Annual Review of Fluid Mechanics Volume 25, pages 99-114, Jan. 1993.

P.M. Moretti & R.L. Lowery, “Heat Exchanger Tube Vibration Characteristics in a `No-Flow' Condition,” TEMA Report, School of Mechanical and Aerospace Engineering, Oklahoma State University, Stillwater, September 1973, OSU Library Special Collections, Call Number 621.4022 M845h.

Excerpted in textbook by Robert D. Blevins, Formulas for Natural Frequency and Mode Shape, Van Nostrand-Reinhold, New York, 1979 (reprinted by Krieger Publ., Malabar, Florida in 1984) - on pages 141 & 200.

Excerpted in textbook by Robert D. Blevins, Formulas for Vibrations, Krieger Publ., Malabar, Florida, 1980 - Figure 8.6 and Reference 8.4.

Excerpted in textbook by Robert D. Blevins, Flow-Induced Vibration - Second Edition, Van Nostrand Reinhold, New York 1990 - in Table 2-2 part 7.

Cited by D.C. Nguyen, et al., “Lowest Natural Frequency of Multiply Supported U-Tubes,” Trans. ASME, J. Press. Vess. Tech., vol. 106, no. 4, pp. 414-416, 1984.

Cited by S.S. Chen, J.A. Jendrzej., & M.W. Wambsganss, “Dynamics of Tubes in Fluid With Tube-Baffle Interaction,” J. Press. Vess., vol. 107, no. 1, pp. 7-17, 1985.

Cited by P.M. Moretti, “Fundamental Frequencies of U-Tubes in Tube Bundles,” J. Press. Vess., vol. 107, no. 2, pp. 207-209, 1985.

P.M. Moretti, “A Critical Review and Analysis of the Literature and Research on Flow-Induced Vibrations in Heat Exchangers,” Paper 86d, 74th AIChE National Meeting, New Orleans, March 14, 1973 (invited paper).

Cited by C.D. Nieh & H. ZengYan, “Estimate Exchanger Vibration,” Hydroc. Proc., vol. 65, no. 4, pp. 61-65, 1986.

Cited by S.Q. Lin & C.N. Bapat, “Extension of Clearance and Impact Force Estimation Approaches to a Beam-Stop System,” J. Sound and Vibration, v. 163, n. 3 (May 22, 1993), pp. 423-428.

P.M. Moretti & R.L. Lowery, “Natural Frequencies and Damping of Tubes in Shell-and-Tube Heat Exchanger“, Paper 86c, AIChE National Meeting, New Orleans, March 14, 1973 (invited paper).

Cited by Y.S. Shin & M.W. Wambsganss, Flow-Induced Vibration in LMFBR Steam Generators: A State of the Art Review, Argonne Report ANL-75-16, May 1975. [#12/13/20]

Cited by Y.S. Shin, J.A. Jendrezej, M.W. Wambsganss, & D.E. Sass, “Experimental Studies of Tube-Baffle Dynamic Interaction in Heat Exchangers,” Trans. Am. Nucl. Soc., vol. 22, pp. 563-566, November 16, 1975.

Cited by Y.S. Shin & M.W. Wambsganss, “Flow-Induced Vibrations in LMFBR Steam Generators - State-of-the-Art-Review,” Nucl. Eng. De., vol. 40, no. 2, pp. 235-284, 1977.

P.M. Moretti, “New Design Criteria for Flow-Induced Vibrations of Vessel Internals,” Transactions American Nuclear Society (ANS) vol. 15, no. 1, p. 338, June 1972.

P.M. Moretti, “Bibliography and Classification of Flow-Induced Vibrations,” Notes for Workshop on Flow-Induced Vibrations, Oklahoma State University, Stillwater, March 8, 1972.

Stratification in Lakes

Ahmed A. Busnaina, David G. Lilley, & Peter M. Moretti, “Prediction of Local Destratification of Lakes,” Proc. ASCE, J. of Hydraulics Division, vol. 107, no. HY3, pp. 259-272, March 1981.

P.M. Moretti et al., “Developing Guidance On: Localized Mixing of Waters to Enhance Reservoir Releases - Phase Two,” Final Report to U. S. Army Corps of Engineers, Waterways Experiment Station, Vicksburg, Miss., Contract No. DACW39-78-C-0045, 300 pages, April 1981.

John J. Moon, D.K. McLaughlin, & P.M. Moretti, “Enhancement of Reservoir Release Water Quality by Localized Mixing : Hydraulic Model Investigation,” First Phase Final Report (Contract DACW 39-78-C-0045) to U.S. Army Engineer Waterways Experiment Station (Vicksburg, Miss.), 1979, Oklahoma State University Library, Special Collections, Call Number 333.91 M818e.

Peter M. Moretti & Dennis K. McLaughlin, “Hydraulic Modeling of Mixing in Stratified Lakes,” (Proc. Paper 12868), ASCE Journal Hydraulics Division, vol. 103, no. HY4, p. 367-380 (April 1977); closure and discussion in vol 105, no. HY8, pp. 1035-1036, August 1979.

Cited by I.V. Muralikrishna & H. Raman, “Hydraulic Modeling of Mixing in Stratified Lakes” Discussion, Paper No. 13507, Proc. ASCE, J. Hydr. Div., vol. 104, no. HY2, pp. 308-309, February 1978.

Cited by J.D. Ditmars, “Hydraulic Modeling of Mixing in Stratified Lakes” Discussion, Proc. Paper No. 14047, Proc. ASCE, J. Hydr. Div., vol. 104, no. HY10, pp. 1463-1466, October 1978.

Cited by A.A. Busnaina, et al., “Prediction of Local Destratification of Lakes,” J. Hydr. ASCE, vol. 107, no. 3, pp. 259-2721, 1981.

Cited by A.A. Busnaina & D.G. Lilley, “Computer Prediction of Local Destratification near Low-Level Release Structures of Reservoirs,” J. Fluid Eng., vol. 105, no. 1, pp. 65-70, 1983.

Cited by K.M. Faust & E.J. Plate, “Experimental Investigation of Intrusive Gravity Currents Entering Stably Stratified Fluids,” J. Hydr. Res., vol. 22, no. 5, pp. 315-325, 1984.

Cited by H.I. Hart, “Thermocline locations and buoyancy effects of stratification,” Discovery and Innovation, v. 10, n. 1-2 (June 1998), pp. 95-98.

P.M. Moretti & D.K. McLaughlin, “Mixing Phenomena in Stratified Lakes,” Technical Completion Report, Oklahoma Water Resources Research Institute, OWRI Project No. A-050-Okla., August 1975.

Cited by J.D. Ditmars, “Mixing and Transport” Review, J. Water P.C., vol. 48, no. 6, pp. 1620-1639, 1976.

Cited by J.D. Ditmars, “Mixing and Transport” Review, J. Water P. C., vol. 50, no. 6, pp. 1402-1406, 1978.

Cited by L. Neal & R. Herwig, “Oxygen Sag and Stream Purification” Review, J. Water P. C., vol. 50, no. 6, pp. 1402-1406 (1978).

Cited by J.D. Ditmars, “Hydraulic Modeling of Mixing in Stratified Lakes” Discussion, Proc. Paper No. 14047, Proc. ASCE, J. Hydr. Div., vol. 104, no. HY10, pp. 1463-1466, October 1978.

Cited by C. Kranenburg, “Destratification of Lakes Using Bubble Columns,” J. Hydr. ASCE Vol. 105, no. 4, pp. 333-347, 1979.

Alternative Energy

Y.I. Sharaf-Eldeen, P.M. Moretti, J.D. Parker, & R.G. Ramakumar, “Evaluation of WECS Performance and Economics in Utility-Interconnected Application,” Proc. of the Seventh ASME Wind Energy Symposium, SED vol. 5, pp. 189-193, New Orleans, Louisiana, January 13, 1988.

Y.I. Sharaf-Eldeen, P.M. Moretti, J.D. Parker, & R.G. Ramakumar, “Performance and Economics of Individually-Owned Wind Systems in Utility-Connected Applications,” Computers in Engineering 1987, Proc. 1987 ASME International Computers in Engineering Conference, vol. 3, pp. 95-100, New York, August 9-13, 1987.

Y.I. Sharaf-Eldeen & P.M. Moretti, “Determination of Optimum Wind-Turbine Design for Utility-Interconnected Applications,” Computers in Engineering 1987, Proc. 1987 ASME International Computers in Engineering Conference, vol. 3, pp. 41-49, New York, August 9-13, 1987.

Y.I. Sharaf-Eldeen, P.M. Moretti, J.D. Parker, & J.H. Mize, “Economics of Wind Energy Conversion Systems in Electric Utility Applications”. Computers in Engineering 1987, Proc. 1987 ASME International Computers in Engineering Conference, vol. 3, pp. 41-49, New York, August 9-13, 1987.

R. Ramakumar & Peter M. Moretti, “Wind Power,” in Marks' Standard Handbook for Mechanical Engineers, 9th edition, ed. E. A. Avallone and T. Baumeister, section 9, pp. 170-175, McGraw-Hill, New York, 1987.

Y.I. Sharaf-Eldeen & P.M. Moretti, “Simulation of Electric Utility Systems with Wind Turbine Generators,” Computers in Engineering 1986, Proc. 1986 ASME International Computers in Engineering Conf. and Exh., ed. G. Gupta, vol. 3, pp. 239-244, Chicago, July 20-24, 1986.

Y.I. Sharaf-Eldeen, P.M. Moretti, & J.D. Parker, “Wind Systems for Residential and Agricultural Applications,” Paper 86-4520, American Society of Agricultural Engineers, Winter Meeting, Chicago, December 1986, 15 pages.

Peter M Moretti & Louis V. Divone, “Modern Windmills,” Scientific American, vol. 254, no. 6, pp. 110-118, June 1986.

Cited by S.L. Zubkovsky, V.M. Lyatkher, M.M. Fedorov, & L.R. Zvang (Acad. Sci. USSR, Inst. Atm. Phys, Moscow V71) “Wind Flow Interaction with a Wind Powerplant,” in Russian, EF577, IAN SSS FAO, vol. 26, no. 9, pp. 899-905, 1990.

R. Sethuram & P. M. Moretti, “Predicting Utility Peaks with and Without Wind Generators,” Solar Energy J., vol. 33, no. 1, p. 89-90, 1984.

Y.I. Sharaf-Eldeen & P.M. Moretti, “Comparison of Methods for Evaluating Impact of Wind Power on Utility Operations,” Proc. of the 2nd ASME Wind Energy Symposium, Houston, Texas, February 1, 1983.

P.M. Moretti, & B.W. Jones, “Analysis Method for Non-Schedulable Generation in Electric Systems,” Solar Energy J., vol. 28, no. 6, July 1982, pp. 499-508.

Cited by T. Sutoh, H. Suzuki, & Y. Sekine, “Economic Evaluation of a Residential Photovoltaic System based on a Probability Model Using Actual Metereological Data,” IEEE Engrg. Conf., vol. 2, no. 1, pp. 9-15, 1987.

P.M. Moretti, & B.W. Jones, “Analysis Method for Non-Schedulable Generation in Electric Systems,” Institute of Energy Analysis report, Oklahoma State University, 1981, OSU Library Special Collections, Call Number 93-009 T73.

P.M. Moretti & R.W. Thresher, “Overview of Wind Energy Systems: Issues in Development and Application,” Trans. ASME, J. of Solar Energy Engineering, vol. 103, no. 3, pp. 3-10, February 1981.

Cited by R. Ramakumar, “Storage Options for Harnessing Wind Energy,” Mechanical Engineering, vol. 105, no. 11, pp. 74-83, November 1983.

Cited by Robert E. Wilson & Robert W. Thresher, “Electrical Energy from the Wind,” Mechanical Engineering, vol. 106, no. 1, January 1984, pages 67 & 69, ASME, N.Y. 1984.

Cited by R.B. Sethuram & P.M. Moretti, “Predicting Utility Peaks With and Without Wind Generators,” Solar Energy, vol. 33, no. 1, pp. 89f, 1984.

Cited by R.A. Schlueter, G.L. Park, T.W. Reddoch, P.R. Barnes, & J.S. Lawler, “A Modified Unit Commitment and Generation Control for Utilities with A Large Wind Generation Penetration,” IEEE Power, vol. 104, no. 7, pp. 1630-1636, 1985.

P.M. Moretti, “Mechanical Power from the Oceans,” in Standard Handbook for Electrical Engineers, ed. D. G. Fink and H. W. Beaty, Eleventh Edition, McGraw-Hill, N.Y., Sections 37-46, pp. 11-22 to 11-25, 1978.

B.W. Jones & P.M. Moretti, “Evaluation of Wind Generator Economics in a Load Duration Context,” presented at IEEE Power Engineering 1977 Winter Meeting, New York, February 4, 1977, published in IEEE Power Engineering Society Papers, Energy Development III., 77 CH 1215-3-PWR, pp. 25-29, 1977.

B.W. Jones, P.M. Moretti, & J.H. Mize, “Dynamic Simulation for Regional Energy Studies,” Proceedings of the 2nd Annual UMR-MEC Conference on Energy, vol. 2, pp. 377f, Rolla, Missouri, October 9, 1975.

Stratification in Thermal Storage

Y.H. Zurigat, A.J. Ghajar, & P.M. Moretti, “Stratified Thermal Storage Tank Inlet Mixing Characterization,” Applied Energy, vol. 30, no. 2, pp. 99-111, 1988.

Cited by Y.H. Zurigat, K.J. Maloney, & A.J. Ghajar, A comparison study of one-dimensional models for stratified thermal storage tanks,” Trans. ASME, J. Sol. Energ. v. 111, n. 3 (Aug. 1989), pp. 204-210.

Cited by A.J. Ghajar & Y.H. Zurigat, “Numerical study of the effect of inlet geometry on stratification in thermal-energy storage,” Numer. Heat Tr. A-Appl. v. 19, n. 1 (Jan.-Feb. 1991), pp. 65-83.

Cited by Y.H. Zurigat, P.R. Liche, & A.J. Ghajar, “Influence of inlet geometry on mixing in thermocline thermal-energy storage,” Int. J. Heat Mass Trans. v. 34, n. 1 (Jan 1991), pp. 115-125.

Cited by J.E.B. Nelson, A.R. Balakrishnan, &S.S. Murthy, “Transient analysis of energy storage in a thermally stratified water tank,” Int. J. Energ. Res. v. 22, n. 10 (Aug. 1998), pp. 867-883.

Y.H. Zurigat, A.J. Ghajar, & P.M. Moretti, “A Comparison Study of Various Models of Stratified Thermal Storage Tanks,” Computers in Engineering 1987, Proc. 1987 ASME International Computers in Engineering Conference, vol. 3, pp. 101-119, New York, August 9-13, 1987.

Fred J. Oppel, Afshin J. Ghajar, & Peter M. Moretti, “Thermal Storage: Keeping Hot and Cold Fluids from Blending,” Consult. Specif. Eng., vol. 1, no. 3, pp. 68-73, March 1987.

F.J. Oppel, A.J. Ghajar, & P.M. Moretti, “Computer Simulation of Stratified Heat Storage,” Applied Energy, vol. 23, no. 3, pp. 205-224, Elsevier Applied Science Publishers, England,.June 1986.

Fred J. Oppel, Afshin J. Ghajar, & Peter M. Moretti, “A Numerical and Experimental Study of Stratified Thermal Storage,” ASHRAE Transactions, vol. 92, part 2, pp. 293-309, 1986.

Y.H. Zurigat, G.M. Hanna, A.J. Ghajar, & P.M. Moretti, “Stratified Thermal Storage Tank Inlet Characterization Using Computer Simulation and Experiment,” Computers in Engineering 1986, Proc. 1986 ASME International Computers in Engineering Conf. and Exh., ed. G. Gupta, vol. 3, pp. 285-289, Chicago, July 20-24, 1986.

F.J. Oppel, H.K. Yoon, A.J. Ghajar, & P.M. Moretti, “Computer Simulation of Stratified Thermal Storage,” Proc. 2nd Joint ASCE/ASME Mechanics Conference, Albuquerque, New Mexico, June 26, 1985.

Boundary-Layer Turbulence

T.D. Reid, P.M. Moretti, & Ayman Said Abu-Mostafa, “Study of Boundary-Layer Transition using Transonic-Cone Preston-Tube Data,” Final Report for research grant NSF-2396, MAE Dept. Oklahoma State University,July 1982, OSU Library Special Collections, Call Number 629.13237 R326s.

P.M. Moretti, invited discussion of “Engineering Approach to the Design of Laminarizing-Nozzle Flows,” American Society of Mechanical Engineers, San Francisco, March 26, 1972, ASME Trans. Series D, J. Basic Engineering, vol. 94, no. 4, p. 903 (1972).

Peter M. Moretti, “Heat Transfer Through an Incompressible Turbulent Boundary Layer with Varying Free-Stream Velocity and Varying Surface Temperature,” Ph.D. Dissertation, Stanford University, January 1965. Also available from University Microfilms, Xerox Corporation, Ann Arbor, Michigan. The text of this dissertation text was also submitted, with Prof. Wm. M. Kays, as an NSF final report “Heat Transfer Through an Incompressible Turbulent Boundary Layer with Varying Free-Stream Velocity and Varying Surface Temperature“, Report No. PG-1, Thermosciences Division, Department of Mechanical Engineering, Stanford University, Stanford, California, November 1964.

Excerpted in textbook by William M. Kays, Convective Heat and Mass Transfer, McGraw-Hill, New York, 1966 - on pages 97, 248, 249, & 252.

Excerpted in textbook by B.E. Launder & D.B. Spaulding, Mathematical Models of Turbulence, Academic Press, London, 1972 - on pages 62, 53, 107, & 160.

Excerpted in textbook by Frank M. White, Viscous Fluid Flow, McGraw-Hill, New York, 1974 - on pages 571, 572, & 697.

Excerpted in textbook by Louis C. Burmeister, Convective Heat Transfer, Wiley, New York 1983 - on pages 403 & 425.

Excerpted in book by Robert J. Moffat & Wm. M. Kays, A Review of Turbulent-Boundary-Layer Heat Transfer Research at Stanford, 1950-1983, Academic Press, New York 1984 - on pages 247f, 280, 264, & 370.

Excerpted in textbook by D.A. Anderson, J.C. Tannehill, & A.H. Pletcher, Computational Fluid Mechanics and Heat Transfer, Hemisphere/McGraw-Hill, New York - on pages 361 & 583.

Cited by F.A. Schraub & S.J. Kline. “A Study of the Structure of the Turbulent Boundary Layer with and without Longitudinal Pressure Gradients,” Report MD-12, Thermosciences Division, Department of Mechanical Engineering, Stanford University, California, 1965.

Cited by B.E. Launder & F.C. Lockwood, “An Aspect of Heat Transfer in Accelerating Turbulent Boundary Layers,” ASME Paper No. 68-WA/HT-13, 1968; also in J. Heat Trans., vol. 91, no. 2, p. 229, 1969; abstracted in Mech. Eng., vol. 91, no. 5, p. 97, May 1969.

Cited by T. Cebeci, A.M.O. Smith, & G. Mosinski, “Solution of Incompressible Turbulent Boundary Layer Equations with Heat Transfer,” ASME Paper No. 69-HT-7, 1969; also in J. Heat Transfer, vol. 92, no. 1, p. 133, 1970; abstracted in Mech. Eng., vol. 92, no. 11, p. 62, Nov. 1970.

Cited by R.W. Hanks, “A Theory of Laminar Flow Stability,” AIChE Journal, vol. 15, no. 1, p. 25, 1969.

Cited by W.P. Jones & B.E. Launder, “Prediction of Laminarization with a 2-Equation Model of Turbulence,” Int. J. Heat and Mass Transfer, vol. 15, no. 2, p. 301, 1972.

Cited by R. Narasimha & K.R. Sreenivasa. “Relaminarization in Highly Accelerated Turbulent Boundary-Layers,” J. Fluid Mech., vol. 61, p. 417, November, 1973.

Cited by M.E. Brun, “Reorganization Criteria in a Cylindrical Straight Linear Pipe,” Cr. Ac. Sci. B. 285, 2, pp. 29-32, 1977.

Cited by R.S. Hawke, “Devices for Launching 0.1 Projectiles to 150 Km/s or more to Initiate Fusion-Railgun Accelerations,” Atomkern-K., vol. 38, no. 1, pp. 35-46, 1981.

Cited by A.C. Buckingham, “Electromagnetic Propulsion - Drag and Erosion Modeling,” AIAA Journal, vol. 19, no. 11, pp. 1422-1428, 1981.

Cited by W. Rodi, “Examples of Turbulence Models for Incompressible Flow,” AIAA Journal, vol. 20, no. 7, pp. 872-879, 1982.

Cited by J. Sucec, “Approximate Analytical Solution to Forced-Convection with Arbitrary Surface Heat Flux,” Int. J. Heat, vol. 32, no. 6, pp. 1189-1192, 1989.

Cited by J. Sucec & Y. Lu, “Heat Transfer across Turbulent Boundary-Boundary Layers with Pressure Gradients,” J. Heat Transfer, vol. 112, no. 4, pp. 906-912, 1990.

P.M. Moretti & W.M. Kays, “Heat Transfer to a Turbulent Boundary Layer with Varying Free-Stream Velocity and Varying Surface Temperature - An Experimental Study,” International Journal of Heat and Mass Transfer, vol. 8, no. 9, pp. 1187-1202, September 1965.

Reviewed by R.J. Ceresuela: Review 3065, Applied Mechanics Reviews, vol. 19, no. 5, p. 439, May 1966.

Cited by L.H. Back, P.F. Massier, & R.F. Cuffel, “Some Observations on Reduction of Turbulent Boundary-Layer Heat Transfer in Nozzles,” AIAA Journal, vol. 4, no. 12, p 2226, 1966.

Cited by E.R.G. Eckert, E.M. Sparrow, W.E. Ibele, & R.J. Goldstein, “Heat Transfer, a Review of Current Literature,” Int. J. Heat Mass Transfer, vol. 9, no. 7, p. 599, 1966.

Cited by J.K. Ferrell & E.P. Stabel, “Heat Transfer,” Ind. Eng. Ch. vol. 58, no. 12, p. 42 (1966).

Cited by L.H. Back, P.F. Massier, & R.F. Cuffel, “Flow Phenomena and Convective Heat Transfer in a Conical Supersonic Nozzle,” J. Spac. Rock., vol. 4, no. 8, p. 1040, 1967.

Cited by R.W. Graham & R.G. Deissler, “Prediction of Flow Acceleration Effects on Turbulent Heat Transfer,” J. Heat Transfer, vol. 89, no. 4, p. 371, 1967.

Cited by B.E. Launder & F.C. Lockwood, “An Aspect of Heat Transfer in Accelerating Turbulent Boundary Layers,” ASME Paper No. 68-WA/HT-13, 1968; also in J. Heat Trans. vol. 91, no. 2, p. 229, 1969; abstracted in Mech. Eng., vol. 91, no. 5, p. 97, May 1969.

Cited by M.A. Narayana, “An Experimental Study of Reverse Transition in 2-Dimensional Channel Flow,” J. Fluid Mech., vol.31, no. 3, p. 609 (1968).

Cited by V.C. Patel & M.R. Head, “Reversion of Turbulent to Laminar Flow,” J. Fluid Mech., vol. 34, no. 2, p. 371, 1968.

Cited by E. Talmor, “Effect of Pressure Gradient on Sonic-Point Heat Transfer,” AIChE Journal, vol. 14, no. 1, p. 127, 1968.

Cited by L.H. Back, P.F. Massier, & R.F. Cuffel, “Laminarization of a Turbulent Boundary Layer in Nozzle Flows,” AIAA Journal, vol. 7, p. 730, 1969.

Cited by L.H. Back, R.F. Cuffel, & P.F. Massier, “Laminarization of a Turbulent Boundary Layer in Nozzle Flow - Boundary Layer and Heat Transfer Measurements with Wall Cooling,” ASME Paper No. 69-HT-56, 1969; also in J. Heat Transfer, vol. 92, no. 3, p. 333, 1970; abstracted in Mech. Eng., vol. 91, no. 11, p. 67, November 1969.

Cited by C.A. Bankston, “The Transition From Turbulent to Laminar Gas Flow in a Heated Pipe,” ASME Paper No. 69-HT-54, 1969.

Cited by C.L. Caldwell & R.A. Seban, “Flow and Heat Transfer in a Laminarizing Turbulent Boundary Layer,” ASME Paper No. 69-HT-10, 1969.

Cited by W.P. Jones & B.E. Launder, “On the Prediction of Laminarescent Turbulent Boundary Layers,” ASME Paper No. 69-HT-13, 1969; abstracted in Mech. Eng., vol. 91, no. 11, p. 65, November 1969.

Cited by A.I. Leontiev, “To the Question of the Impairment of Turbulent Convection Heat Transfer at Supercritical Pressure at Forced Flow of Fluid in the Vertical Channels,” ASME Paper No. 69-HT-60, 1969.

Cited by W.B. Hall & J.D. Jackson, “Laminarization of a Turbulent Pipe Flow by Buoyancy Forces,” ASME Paper No. 69-HT-55, 1969.

Cited by W.M. Kays, R.J. Moffat, & W.H. Thielbahr, “Heat Transfer to the Highly Accelerated Turbulent Boundary Layer With and Without Mass Addition,” ASME Paper No 69-HT-53, 1969; also in J. Heat Transfer, vol. 92, no.3, p. 499, 1970.

Cited by B.E. Launder & W.P. Jones, “Sink Flow Turbulent Boundary Layers,” J. Fluid Mech., vol. 38, no. 4, p. 817, 1969.

Cited by M.A. Narayana & V. Ramjee, “On Criteria for Reverse Transition in a 2-Dimensional Boundary Layer Flow,” J. Fluid Mech., vol. 35, no. 2, p. 255; 1969; see also Z. Ang. Math., vol.18, no. 5, p. 642, 1967.

Cited by W.Rodi, W.T. Pennell, & E.R.G. Eckert, “Laminarization of Turbulent Flow in a Circular Porous Tube with Uniform Mass Injection Through the Tube Wall,” ASME Paper No. 69-HT-57, 1969.

Cited by L.H. Back, “Acceleration and Cooling Effects in Laminar Boundary Layers - Subsonic, Transonic, and Supersonic Speeds,” AIAA Journal, vol. 8, p. 794, 1970.

Cited by C.W. Coon & H.C. Perkins, “Transition From Turbulent to Laminar Regime for Internal Convective Flow with Large Property Variations,” J. Heat Transfer, vol. 92, no. 3, p. 506, 1970.

Cited by D.M. McEligot, C.W. Coon, & H.C. Perkins, “Relaminarization in Tubes,” Int. J. Heat Mass Transfer, vol. 13, no. 2, p. 431, 1970.

Cited by E. Talmor & N. Weber, “Heat Transfer From Boundary Layers Undergoing an Acceleration-Induced Reverse Transition,” AIChE Journal, vol. 16, no. 3, p. 446, 1970.

Cited by M. Miya, D.E. Woodmans, & T.J. Hanratty, “Model for Roll Waves in Gas-Liquid Flow,” Chem. Eng. Sci., vol. 26, no. 11, p. 1915, June 1971.

Cited by A. Steiner, “Reverse Transition of a Turbulent-Flow Under Action of Buoyancy Forces,” J. Fluid Mech., vol. 47, p. 503, June 14, 1971.

Cited by R.F. Blackwell & L.S. Kovasznay, “Large-Scale Motion of a Turbulent Boundary-Layer During Relaminarization,” J. Fluid Mech., vol. 53, p. 61, May 9, 1972.

Cited by G.L. Donohue, W.G. Tiederman, & M.M. Reischman, “Flow Visualization of the Near-Wall Region in a Drag-Reducing Channel Flow,” J. Fluid Mech., vol. 56, p. 559, December 12, 1972.

Cited by G.H. Christopher, R.C. Lessman, & F.M. White, “Calculation of Turbulent Heat Transfer and Skin Friction,” AIAA Journal, vol. 11, 7, pp. 1046-1048, 1973.

Cited by W.P. Jones & B.E. Launder, “Calculation of Low-Reynolds-Number Phenomena with a 2-Equation Model of Turbulence,” Int. J. Heat and Mass Transfer, vol. 16, no. 6, p. 1119, 1973.

Cited by D.W. Kearney, W.M. Kays, & R.J. Moffatt, “Heat Transfer to a Strongly Accelerated Turbulent Boundary Layer - Some Results Including Transpiration,” Int. J. Heat and Mass Transfer, vol. 16, no. 6, p. 1289, 1973.

Cited by K.R. Perkins, K.W. Schade & D.M. McEligot, “Heated Laminarizing Gas Flow in a Square Duct,” Int. J. Heat and Mass Transfer, vol. 16, no. 3, p. 897, 1973.

Cited by H. Tanaka, A. Tsage, M. Hirata, & H. Nishiwak, “Effects of Buoyancy and of Acceleration Owing to Thermal Expansion on Forced Turbulent Convection in Vertical Circular Tubes-Criteria of Effects, Velocity, and Temperature Profiles, and Reverse Transition From Turbulent to Laminar-Flow,” Int. J. Heat and Mass Transfer, vol. 16, no. 6, p. 1267, 1973.

Cited by R. Narasimha & K.R. Sreenivasa. “Relaminarization in Highly Accelerated Turbulent Boundary-Layers,” J. Fluid Mech., vol. 61, p. 417, November, 1973.

Cited by M.M. Nazarchu & V.M. Panchenk, “Effect of Negative-Pressure Gradients on Character of Surface Friction Changes at Subcritical Regimes of Gas-Flow in Tubes” (in Russian), Dop. Ukr. A 1974, 4, p. 331, 1974.

Cited by R.G. Deissler, “Evolution of Heat-Transfer andFlow in Moderately Short Turbulent Boundary-Layers in SeverePressure-Gradients,” Int. J. Heat and Mass Transfer, vol. 17, no. 9, p. 1079, 1974.

Cited by K.R. Perkins & D.M. McEligot, “Viscous Sublayer Measurements for Air Flows Laminarized by Heating,” AIAA Paper No. 74-704 and ASME Paper No. 74-HT-24, AIAA/ASME Thermophysics and Heat Transfer Conference, Boston, July 15-17, 1974.

Cited by J.R.L.Allen, “Development of Flute-Mark Assemblages 2 - Evolution of Trios of Defects,” Sedimentary Geology, vol. 13, no. 1, pp. 1-26, 1975.

Cited by B. Schulzjander, “Heat-Transfer Calculations in Turbulent Boundary-Layers Using Integral Relations,” Acta Mechanica, vol. 21, no. 4, pp. 301-312, 1975.

Cited by H.H. Fernholz, “External Flows” Review, Trans. Appl. Phys. (Book #04990) vol. 12, pp. 45-107, 1976/8.

Cited by C. Mari, D. Jeandel, & J. Mathiew, “Computing Method for Compressible Turbulent Boundary-Layer with Heat-Transfer“, (in French), Int. J. Heat, vol. 19, no. 8, pp. 893-899, 1976.

Cited by H. Tanaka & J. Shimizu, “Laminarization in Low Reynolds-Number Turbulent Duct Flows,” J. Heat Trans., vol. 99, no. 4, pp. 682-684, 1977.

Cited by W. Winkler & U. Grigull, “Compressible Turbulent Boundary-Layer Heat Transfer with Strong Favorable Pressure-Gradients (Heat Transfer in a Convergent-Divergent Nozzle),” (in German) Wärme. Stoff., vol. 10, no. 4, pp. 281-291, 1977.

Cited by K. Mastanaiah, “Prediction of Skin-Friction and Heat Transfer from Compressible Turbulent Boundary Layers in Rocket Nozzles,” Int. J. Heat, vol. 21, no. 11, pp. 1403-1410, 1978.

Cited by C.B. Thorsness & T.J. Hanratty, “Mass Transfer between a Flowing Fluid and a Solid Wavy Syrface“ and “Stability of Dissolving or Depositing Surfaces,” AIChE Journal, vol. 25, no.4, pp. 686-697 and 697-701, 1979.

Cited by R. Narasimha & K.R. Sreenivasa. “Relaminarization of Fluid Flows,” Book #11361, vol. 19, pp. 221-309, 1979.

Cited by F.L. Test & R.C. Lessmann, “An Experimental Study of Heat Transfer During Forced Convection Over a Rectangular Body,” J. Heat Tran. vol. 102, no. 1, pp. 146-151, 1980.

Cited by Y. Shina, et al., “Measurement of Reverse Transition in Converging Duct Flow,” J. Nuc. Sci. T., vol. 17, no. 11, pp. 869-871, 1980.

Cited by R.R. Gilpin, “Ice Formation in a Pipe Containing Flows in the Transition and Turbulent Regimes,” J. Heat Trans. Vol. 103, no. 2, pp. 363-368, 1981.

Cited by F.L. Test, et al., “Heat Transfer During Wind Flows Over Rectangular Bodies in the Natural Environment,” J. Heat Trans. vol. 103, no. 2, pp. 262-267, 1981.

Cited by D. Thomas Lindon, “Turbulent Boundary Layer Flow: A Law of the Wake for T+,” ASME Paper at Winter Annual Meeting 1980; and Trans. ASME, J. Heat Transfer.

Cited by K.R. Sreenivasan, “Laminarescent, Relaminarized, and Retransitional Flows,” Act. Mechan., vol. 44, no. 1-2, pp. 1-48, 1982.

Cited by H. Tanaka, H. Kawamura, A. Tatena, & S. Hatamiga, “Effect of Laminarization on Heat-Transfer for Low Reynolds-Number Flow Through a Converging to Constant Area Duct,” J. Heat Tran., vol. 104, no. 2, pp. 363-371, 1982.

Cited by F.W. Chambers, H.D. Murphy, & D.M. McEligot, “Laterally Converging Flow: 2. Temporal Wall Shear Stress,” J. Fluid Mech., vol. 127, pp. 403-428, February 1983.

Cited by N. Hay, D. Lampard, & C.L. Saluja, “Effects of the condition of the Approach Boundary Layer and of Mainstream Pressure Gradients on the Heat-Transfer Coefficient on Film-Cooled Surfaces,” J. Eng. Gas T., vol. 107, no. 1, pp. 99-104, 1985.

Cited by M. Iguchi, M. Ohmi, & K. Nishizawa, “Relaminarization of Pulsatile Turbulent-Flow in a Rectangular Duct,” B. JSME, vol. 29, no. 247, pp. 59-66, 1986.

Cited by G. Tanaka, S. Marugawa, & S. Hatana, “Combined Forced and Natural-Convection Heat-Transfer for Upward Flow in a Uniformly Heated, Vertical Pipe,” Int. J. Heat, vol. 30, no. 1, pp. 165-174, 1987.

Cited by T. Hirata & H. Matsuzawa, “A Study of Ice-Formation Phenomena on Freezing of Flowing Water in a Pipe,” Trans. ASME, J. Heat Transfer, vol. 109, no. 4, pp. 965-970, 1987.

Cited by D.S. Finnicum & T.J. Hanratty, “Effect of Favorable Pressure-Gradients on Turbulent Boundary Layers,” AIChE Journal, vol. 34, no. 4, pp. 529-540, 1988.

Cited by R.H. Pletcher, “Progress in Turbulent Forced Convection,” J. Heat Transfer, vol. 110, no. 4B, pp. 1129-1144, 1988.

Cited by D. Biswas, H. Yamasaki, T. Matsui, Y. Saito, & S. Shioda, “Studies on Supersonic Radial Flow Behavior in Disk Channel,” Japan. Soc. Mech. Eng. JSME II, vol. 32, no. 4, pp. 574-582, 1989.

Cited by J. Sucec & Y. Lu, “Heat Transfer across Turbulent Boundary-Boundary Layers with Pressure Gradients,” J. Heat Transfer, vol. 112, no. 4, pp. 906-912, 1990.

Cited by B. Weigand & H. Beer, “Ice-Formation Phenomena for Water Flow inside a Cooled Parallel-Plate Channel - an experimental and theoretical study of wavy ice-layers,” Int. J. Heat and Mass Transfer, v. 36, n. 3 (Feb. 1993), pp. 685-693.

Cited by M. Tago, S. Fukusako, M. Yamada, & A. Horibe, “Experimental Study of Ice-Layer Transition Phenomena in a Rectangular Duct containing Water-Flow,” Wärme Stoff, v. 28 (1993), n. 1-2, pp. 37-47.

Cited by B. Weigand & H. Beer, “A theoretical and experimental investigation of smooth-ice and wavy-ice layers in laminar and turbulent flow inside an asymmetrically cooled parallel-plate channel,” Wärme Stoff, v. 29 (1993), p. 27-36.

Cited by R.M.C. So, “Pressure-Gradient Effects on Reynolds Analogy for Constant-Property Equilibrium Turbulent Boundary-Layers,” Int. J. Heat, v. 37 (1994), n. 1, pp. 27-41.

Cited by Z.X. Mao & T.J. Hanratti, “Influence of Large-Amplitude Oscillations on Turbulent Drag,” AIChE J., v. 40 (1994), n. 10, pp. 1601-1610.

Cited by J. Braun & H. Beer, “Ice Formation for Turbulent-Flow in Curved Rectangular Channels,” Int. J. Heat and Mass Transfer, v. 38 (1995), n. 8, pp. 1505-1515.

Cited by T.M. Huang, C. Gau, & W. Aung, “Mixed-Convection Flow and Heat-Transfer in a Heated Vertical Coinvergent Channel,” Int. J. Heat and Mass Transfer, v. 38 (1995), n. 13, pp. 2445-2456.

Cited by M. Tago, S. Fukusako, M. Yamada, & A. Horibe, “Forced-Convection Freezing Heat-Transfer Characteristics in a Return Bend with a Rectangular Cross-Section,” Heat and Mass Transfer, v. 30 (1995), n. 4, pp. 205-214.

Cited by F.M. Fang & C. Farell, “Turbulent Boundary-Layer Characteristics along the Centerline of a Contracting Wall,” J. Wind Engineering and Industrial Aerodynamics, v. 61 (1996), n. 2-3, pp. 131-151.

Cited by D.K. Heist & F.C. Gouldin, “Turbulent-Flow Normal to a Triangular Cylinder,” J. of Fluid Mechanics, v. 331 (Jan. 1997), pp. 107-125.

Cited by K. Itoh, Y. Tsuji, H. Nakamura, & Y. Kukita, “Initial free-surface instabilities on a high-speed water jet simulating a liquid-metal target,” Fusion Technology, v. 36, n. 1 (July 1999), pp.69-84.

Cited by A. Singh, B.D. Vyas, & U.S. Powle, “Investigation of inward flow between two stationary parallel disks,” Int. J. of Heat and Fluid Flow, v. 20, n. 4 (Aug. 1999), pp. 395-401.

Cited by K.J. Rinck & H. Beer, “Solidification inside an axially rotating pipe containing a turbulent liquid flow,” Int. J. Heat and Mass Transfer, v. 42, n. 23 (Dec. 1999), pp. 4375-4389.

Cited by K. Itoh, Y. Tsuji, H. Nakamura, & Y. Kukita, “Free-surface shear-layer instabilities on a high-speed liquid jet,” Fusion Technology, v. 37, n. 1 (Jan. 2000), pp.74-88.

Miscellaneous Topics

Peter M. Moretti, “In With The New“ (Letter), Mensa Bulletin, No. 363, p. 8, January/February 1993.

R. L. Swaim & P. M. Moretti, “A Case for a 120 Semester Credit Hours B.S. in Engineering“, 26th Annual Meeting of the Midwest Section, ASEE, Fayetteville, Arkansas, March 13-15, 1991; also published in ASEE Journal.

Cited and discussed in numerous letters in subsequent issues of Engineering Education.

P.M. Moretti, Letter, Byte, vol. 10, p. 299, Oct. 1985.

Cited by B. Ostrander, letter, Byte, vol. 10, no. 12, p. 367, 1985.

Cited by N. Pole, letter, Byte, vol. 10, no. 10, p. 310, 1985.

P.M. Moretti, “Forum” (Editorial), Autoweek, Feb. 6, 1984.

P.M. Moretti, “More Metrics” (Letter), Mech. Engrg., vol. 98, no. 2, p. 38, 1976.

P.M. Moretti, numerous critical discussions in Applied Mechanics Reviews, 1971-72.

P.M. Moretti, discussion quoted in Proceedings of the Conference of Flow-Induced Vibrations in Reactor System Components, Argonne, May 14-15, 1970, Report ANL-7685, pp. 219-220.

P.M. Moretti et al., Westinghouse Advanced Reactor Division Reports on nuclear-reactor vibrations, modeling, and testing, WARD-FRA-10, -16, -54, -59, -66, -74, -89, -95, -98, -100, -137, & -143, 1968-1970.

Peter M. Moretti & Reiner Schmidt, “Epithermal Molten Salt Thorium Breeders,” Atomwirtschaft, vol. XI, no. 6, p. 319, in German; English abstract on page A 202; June 1966.

Expanded in P.M. Moretti, et al., “Untersuchungen über die Verwendbarkeit von Fluoridsalzschmelzen als Kernbrennstoffträger in epithermischen Thorumreactoren,” Report INTAT-44, INTERATOM, Bensberg/Cologne, Germany, June 1966.