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Welcome to my publications page. This is a personal website I use to host all of my papers that have been peer reviewed and accepted.
Welcome to my publications page. This is a personal website I use to host all of my papers that have been peer reviewed and accepted.
[12 ] Hellmund, N., Inguva, V., & Steiner, D. (2025). Evaluation of emulsification behavior of two dual centrifuge types aided by CFD simulation. International Journal of Pharmaceutics, 126366.
[12 ] Hellmund, N., Inguva, V., & Steiner, D. (2025). Evaluation of emulsification behavior of two dual centrifuge types aided by CFD simulation. International Journal of Pharmaceutics, 126366.
[11 ] Muegge, N., Kronberg, A., Glushenkov, M., Inguva, V., & Kenig, E. Y. (2022). A Thermal Model for Recuperative Heat Engines Operating with Dense Working Fluids. Chemical Engineering Transactions, 96, 175-180.
[11 ] Muegge, N., Kronberg, A., Glushenkov, M., Inguva, V., & Kenig, E. Y. (2022). A Thermal Model for Recuperative Heat Engines Operating with Dense Working Fluids. Chemical Engineering Transactions, 96, 175-180.
[10 ] Al-Lami, A. J., Inguva, V., & Kenig, E. Y. (2022). Numerical analysis of Conjugate Heat Transfer within Internally Channeled Tubes. Applied Thermal Engineering, 119596.
[10 ] Al-Lami, A. J., Inguva, V., & Kenig, E. Y. (2022). Numerical analysis of Conjugate Heat Transfer within Internally Channeled Tubes. Applied Thermal Engineering, 119596.
[9] Inguva, V., Feldmann, N., Claes, L., Koturbash, T., Hahn‐Jose, T., Koutcherov, V., & Kenig, E. Y. (2022). An explicit symplectic approach to solving the wave equation in moving media. Engineering Reports, e12573.
[9] Inguva, V., Feldmann, N., Claes, L., Koturbash, T., Hahn‐Jose, T., Koutcherov, V., & Kenig, E. Y. (2022). An explicit symplectic approach to solving the wave equation in moving media. Engineering Reports, e12573.
[8] Inguva, V., Kenig, E. Y., & Perot, B. J. (2022). A front-tracking method for two-phase flow simulation with no spurious currents. Journal of Computational Physics, 111006.
[8] Inguva, V., Kenig, E. Y., & Perot, B. J. (2022). A front-tracking method for two-phase flow simulation with no spurious currents. Journal of Computational Physics, 111006.
[7] Schulz, A., Wecker, C., Inguva, V., Lopatin, A. S., & Kenig, E. Y. (2021). A PLIC-based method for species mass transfer at free fluid interfaces. Chemical Engineering Science, 117357.
[7] Schulz, A., Wecker, C., Inguva, V., Lopatin, A. S., & Kenig, E. Y. (2021). A PLIC-based method for species mass transfer at free fluid interfaces. Chemical Engineering Science, 117357.
[6] Liu, C., Van Berkel, G. J., Kovarik, P., Perot, J. B., Inguva, V., & Covey, T. R. (2021). Fluid Dynamics of the Open Port Interface for High-Speed Nanoliter Volume Sampling Mass Spectrometry. Analytical Chemistry. Published. https://doi.org/10.1021/acs.analchem.1c01312
[6] Liu, C., Van Berkel, G. J., Kovarik, P., Perot, J. B., Inguva, V., & Covey, T. R. (2021). Fluid Dynamics of the Open Port Interface for High-Speed Nanoliter Volume Sampling Mass Spectrometry. Analytical Chemistry. Published. https://doi.org/10.1021/acs.analchem.1c01312
[5] Inguva, V., Schulz, A., & Kenig, E. Y. (2020). On methods to reduce spurious currents within VOF solver frameworks. Part 1: a review of the static bubble/droplet. Chemical Product and Process Modeling, 1(ahead-of-print).
[5] Inguva, V., Schulz, A., & Kenig, E. Y. (2020). On methods to reduce spurious currents within VOF solver frameworks. Part 1: a review of the static bubble/droplet. Chemical Product and Process Modeling, 1(ahead-of-print).
[4] Inguva, V., Graceffa, R., Schulz, J., Bilsel, O., & Perot, B. J. (2019). Creating round focused micro-jets from rectangular nozzles. Journal of Mechanical Science and Technology, 33(9), 4281-4289.
[4] Inguva, V., Graceffa, R., Schulz, J., Bilsel, O., & Perot, B. J. (2019). Creating round focused micro-jets from rectangular nozzles. Journal of Mechanical Science and Technology, 33(9), 4281-4289.
[3] Inguva, V., Rothstein, J. P., Bilsel, O., & Perot, B. J. (2018). High-speed velocimetry in microfluidic protein mixers using confocal fluorescence decay microscopy. Experiments in Fluids, 59(12), 177.
[3] Inguva, V., Rothstein, J. P., Bilsel, O., & Perot, B. J. (2018). High-speed velocimetry in microfluidic protein mixers using confocal fluorescence decay microscopy. Experiments in Fluids, 59(12), 177.
[2] Bader, S. H., Inguva, V., & Perot, J. B. (2018). Improving the efficiency of wind farms via wake manipulation. Wind Energy, 21(12), 1239-1253.
[2] Bader, S. H., Inguva, V., & Perot, J. B. (2018). Improving the efficiency of wind farms via wake manipulation. Wind Energy, 21(12), 1239-1253.
[1] Inguva, V., Kathuria, S. V., Bilsel, O., & Perot, B. J. (2018). Computer design of microfluidic mixers for protein/RNA folding studies. Plos one, 13(6), e0198534.
[1] Inguva, V., Kathuria, S. V., Bilsel, O., & Perot, B. J. (2018). Computer design of microfluidic mixers for protein/RNA folding studies. Plos one, 13(6), e0198534.
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