Advanced search
Publication Cover
Journal of Microwave Power and Electromagnetic Energy Volume 41, 2006 - Issue 4
Submit an article Journal homepage
188
Views
0
CrossRef citations to date
0
Altmetric
Original Articles

High Frequency Electromagnetism, Heat Transfer and Fluid Flow Coupling in ANSYS Multiphysics

Cristina M. SabliovBiological and Agricultural Engineering Department, Louisiana State University Agricultural Center, Baton Rouge, LA, USACorrespondence[email protected]
,
Deepti A. SalviBiological and Agricultural Engineering Department, Louisiana State University Agricultural Center, Baton Rouge, LA, USA
&
Dorin BoldorBiological and Agricultural Engineering Department, Louisiana State University Agricultural Center, Baton Rouge, LA, USA
Pages 5-17 | Accepted 26 Aug 2007, Published online: 09 May 2016

References

  • ANSYS (1995–2007). ANSYS, Inc., Southpointe, 275 Technology Dr., Canonsburg, PA 15317, http://www.ansys.com
  • Balbastre, J.V., E. Reyes, M.C. Nuno and C. Plaza (2006). “Design Guidelines for Applicators Used in the Microwave Heating of High Losses Material.” In: Advances in Microwave and Radio Frequency Processing, M. Willert-Porada (Ed), pp.31–38, Springer.
  • Bird, R.B., W.E. Stewart and E.N. Lightfoot (1960). Transport Phenomenon, Wiley.
  • Campanone, L.A. and N.E. Zaritzky (2005). “Mathematical Analysis of Microwave Heating Process.” J. Food Engineering, 69, pp.359–368.
  • Choi, Y. and M.R. Okos (1986). “Effects of Temperature and Composition on the Thermal Properties of Foods.” In: Food Engineering and Process Applications, Vol. 1, Transport Phenomenon, M. Le Maguer and P. Jelen (Eds), pp.93–101, Elsevier.
  • Datta, A., H. Prosetya and W. Hu (1992). “Mathematical Modeling of Batch Heating of Liquids in a Microwave Cavity.” J. Microwave Power and Electromagnetic Energy, 27(1), pp.38–48.
  • Falqui-Cao, C., Z. Wang, L. Urruty, J. Pommier and M. Montury (2001). “Focused Microwave Assistance for Extracting Some Pesticide Residues from Strawberries into Water Before Their Determination by SPME/HPLC/DAD.” J. Agricultural and Food Chemistry, 49, pp.5092–5097.
  • Geankoplis, C. J. (1993). Transport Processes and Unit Operations, McGraw-Hill.
  • Gerbo, N.M., D. Boldor and C.M. Sabliov (2007). “Microwave Heating of Pumpable Fluids Using IR Imaging and Fiber Optic Technology.” J. Microwave Power and Electromagnetic Energy. Submitted.
  • Komarov, V.V. and J.M. Tang. (2004). “Dielectric Permittivity and Loss Factor of Tap Water at 915 MHz.” Microwave and Optical Technology Letters, 42(5), pp.419–420.
  • Komarov, V.V. and V.V. Yakovlev (2001). “Simulations of Components of Microwave Heating Applicators by FEMLAB, MicroWaveLab and QuickWave-3D.” Proc. 36th Microwave Power Symp., (San Francisco, CA, April 2001), pp.1–4.
  • Komarov, V.V. and V.V. Yakovlev (2007). “CAD of Efficient TMmn0 Single-mode Elliptical Applicators with Coaxial Excitation.” J. Microwave Power and Electromagnetic Energy, 40(3), pp.174–185
  • Metaxas, A.C. and R.J. Meredith (1983). Industrial Microwave Heating, Peter Peregrinus.
  • Mudgett, R.E. (1986). “Microwave Properties and Heating Characteristics of Foods.” Food Technology, 40 (6), pp.84–93.
  • Le Bail, A., T. Koutchma and H.S. Ramaswamy (2000). “Modeling of Temperature Profiles Under Continuous Tube-flow Microwave and Steam Heating Conditions.” J. Food Process Engineering, 23, pp.1–24.
  • Lin, Y.E., R.C. Anantheswaran and V.M. Puri (1995). “Finite Element Analysis of Microwave Heating of Solid Foods.” J. Food Engineering, 25, pp. 85–112.
  • Ohlsson, T. (1993). “In-flow Microwave Heating of Pump-able Foods.” In: Developments in Food Engineering: Proc. 6th Intern. Congress on Engineering and Food, pp.322–324.
  • Oliveira, M.E.C. and A.S. Franca (2002). “Microwave Heating of Foodstuffs.” J. Food Engineering, 53, pp.347–359.
  • Pandit, R.B. and S. Prasad (2003). “Finite Element Analysis of Microwave Heating of Potato-Transient Temperature Profiles.” J. Food Engineering, 60, pp.193–202.
  • Ratanadecho, P., K. Auki and M. Akahori (2002). “A Numerical and Experimental Investigation of the Modeling of Microwave Heating for Liquid Layers Using a Rectangular Waveguide (Effects of Natural Convection and Dielectric Properties).” Applied Mathematical Modeling, 26, pp.449–472.
  • Regier, M. and H. Schubert (2005). “Introducing Microwave Processing of Food: Principles and Technologies.” In: The Microwave Processing of Foods, H. Schubert and M. Regier (Eds), CRC Press, pp. 3–21.
  • Romano, V.R., F. Marra and U. Tammaro (2005). “Modeling of Microwave Heating of Foodstuff: Study on the Influence of Sample Dimensions with a FEM Approach.” J. Food Engineering, 71, pp.233–241.
  • Sabliov, C.M., K.P. Sandeep and J. Simu-novic (2004). “High Frequency Electro-magnetism Coupled with Conductive Heat Transfer-a Method to Predict Temperature Profiles in Materials Heated in a Focused Microwave System.” In: Microwave and Radio Frequency Applications, Proc. 4th World Congress on Microwave and Radio Frequency Applications, R.L. Shulz and D. Folz (Eds), Microwave Working Group, pp.469476.
  • Salvi, D.A., D. Boldor, C.M. Sabliov and K.A. Rusch (2007). “Numerical and Experimental Analysis of Continuous Microwave Heating of Ballast Water as Preventive Treatment for Introduction of Invasive Species.” J. Marine Environmental Engineering. Submitted.
  • Tang, J. (2005). “Dielectric Properties of Foods.” In: The Microwave Processing of Foods, H. Schubert, and M. Regier (Eds), CRC Press, pp.21–40.
  • Yakovlev, V.V. (2000). “Commercial EM Review Codes Suitable for Modeling of Microwave Heating-a Comparative Review.” In: Scientific Computing in Electrical Engineering, Lecture Notes in Computational Sciences and Engineering, Vol. 18, U. van Reinen, M. Gunther and D. Hecht (Eds.), Springer, pp.87–96.
  • Yakovlev, V.V. (2006). “Examination of Contemporary Electromagnetic Software Capable of Modeling Problems of Microwave Heating.” In: Advances in Microwave and Radio Frequency Processing, M. Willert-Porada (Ed), Springer, pp.178–190.
  • Zhang, J. and A.K. Datta (2006). “Mathematical Modeling of Bread Baking Process.” J. Food Engineering, 75, pp.78–89.
  • Zhou, L., V.M. Puri, R.C. Anantheswaran and G. Yeh (1995). “Finite Element Modeling of Heat and Mass Transfer in Food Materials During Microwave Heating-Model Development and Validation.” J. Food Engineering, 25, pp.509–529.
  • Zhu J., A.V. Kuznetsov and K.P. Sandeep (2007a). “Numerical Simulation of Forced Convection in a Duct Subjected to Microwave Heating.” Heat Mass Transfer, 43(3), pp.255–264
  • Zhu J., A.V. Kuznetsov and K.P. Sandeep (2007b). “Mathematical Modeling of Continuous Flow Microwave Heating of Liquids (Effects of Dielectric Properties and Design Parameters).” Intern. J. Thermal Sciences, 46 (4), pp.328–341.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.