[1. Brandt H.: Modellversuche mit Schiffspropellern an der Wasseroberfiache, Schiff und Hafen. 25(5), 1973, pp.415–422.]Search in Google Scholar
[2. Cox B.D.: Hydrofoil theory for vertical water entry, PhD thesis, Massachusetts Institute of Technology, Cambridge, MA, USA, 1971.]Search in Google Scholar
[3. Dinh N.N.: Some Experiments on a Supercavitating Plane Hydrofoil with Jet-Flap, J. Ship Research, SNAME, 1968, pp. 207-219.]Search in Google Scholar
[4. Faltinsen O.M., Semenov Y.A.: Nonlinear problem of flat-plate entry into an incompressible liquid. J. Fluid Mech. 611, 2008, pp. 151–173.10.1017/S0022112008002735]Search in Google Scholar
[5. Farsi M., Ghadimi P.: Finding the best combination of numerical schemes for 2D SPH simulation of wedge water entry for a wide range of dead-rise angles. Int. J Naval Archit. Ocean Eng. 6, 2014, pp. 638-651.10.2478/IJNAOE-2013-0202]Search in Google Scholar
[6. Farsi M., Ghadimi P.: Effect of flat deck on catamaran water entry through smoothed particle hydrodynamics. Institution of Mechanical Engineering Part M, J. Engineering for the Maritime Environment, March, 2014, published online.10.1177/1475090214563960]Search in Google Scholar
[7. Farsi M., Ghadimi P.: Simulation of 2D symmetry and asymmetry wedge water entry by smoothed particle hydrodynamics method. J. Brazilian Society of Mech. Sci. Eng. 37(3), 2015, pp. 821-835.10.1007/s40430-014-0212-5]Search in Google Scholar
[8. Feizi Chekab M.A., Ghadimi P., Farsi M.: Investigation of three-dimensionality effects on aspect ratio on water impact of 3D objects using smoothed particle hydrodynamics method. J. Brazilian Soc. Mech. Sci. Eng, 2015, published online: June 2015. DOI: 10.1007/s40430-015-0367-8.10.1007/s40430-015-0367-8]Search in Google Scholar
[9. Furuya O.: A performance-prediction theory for partially submerged ventilated propellers. J. Fluid Mechanics, 151, 1985, pp. 311-335.10.1017/S0022112085000982]Search in Google Scholar
[10. Ghadimi P., Saadatkhah A., Dashtimanesh A.: Analytical solution of wedge water entry by using Schwartz–Christoffel conformal mapping. Int. J. Modeling, Simulation and Scientific Computing. 2(3), 2011, pp. 337-354.10.1142/S1793962311000487]Search in Google Scholar
[11. Ghadimi P., Dashtimanesh A., Djeddi S.R.: Study of water entry of circular cylinder by using analytical and numerical solutions. J. Brazilian Society of Mech. Sci. Eng. 37(3),, 2012, pp. 821-83510.1590/S1678-58782012000300001]Search in Google Scholar
[12. Ghadimi P., Feizi Chekab MA., Dashtimanesh A.: A numerical investigation of the water impact of an arbitrary bow section. ISH J. Hydraul. Eng. 19(3), 2013, pp. 186-195.10.1080/09715010.2013.796690]Search in Google Scholar
[13. Ghadimi P., Feizi Chekab MA., Dashtimanesh A.: Numerical simulation of water entry of different arbitrary bow sections. J Naval Archit. Marine Eng. 11 (2), 2014, pp. 117-129.10.3329/jname.v11i2.18724]Search in Google Scholar
[14. Hadler J.B., Hecker R.: Performance of Partially Submerged Propellers, Proc. 7th ONR Symposium on Naval Hydrodynamics, Rome, Italy. 1968.]Search in Google Scholar
[15. Hecker R.: Experimental Performance of a Partially Submerged Propeller in Inclined Flow, SNAME Spring Meeting, Lake Buena Vista, Florida, USA, 1973.]Search in Google Scholar
[16. Javanmardi N., Ghadimi P.: Hydroelastic analysis of surface piercing hydrofoil during initial water entry phase, J. Scientia Iranica, accepted to be published, 2017.10.24200/sci.2017.20010]Search in Google Scholar
[17. Javanmardi N., Ghadimi P.: Hydroelastic analysis of a semi submerged propeller using simultaneous solution of Reynolds averaged Navier–Stokes equations and linear elasticity equations, Journal of Engineering for Maritime Environment,? 2017.10.1177/1475090217691864]Search in Google Scholar
[18. Ji B., Luo X.W., Wang X., Peng X.X., Wu Y.L., Xu H.Y.: Unsteady numerical simulation of cavitating turbulent flow around a highly skewed model marine propeller. J. Fluids Eng.-Trans, ASME, 133 (1), 011102, 2011.10.1115/1.4003355]Search in Google Scholar
[19. Khabkkhpasheva TI, Kim Y, Korobkin AA.: Generalized Wagner Model of Water Impact by Numerical Conformal Mapping. App. Ocean Res. 44, 2014, pp. 29-38.10.1016/j.apor.2013.10.007]Search in Google Scholar
[20. Kruppa CFL.: Testing of Partially Submerged Propellers, Proc. 13th ITTC Report on Cavitation. Berlin & Hamburg, Germany, 1972.]Search in Google Scholar
[21. Kudo T., Ukon Y.: Calculation of super cavitating propeller performance using a vortex-lattice method, in: Second International Symposium on Cavitation, Tokyo, Japan, 1994.10.2534/jjasnaoe1968.1994.47]Search in Google Scholar
[22. Kudo T., Kinnas S.: Application of vortex/source lattice method on supercavitating propellers, in 24th American Towing Tank Conference, College Station, TX, USA, 1995.10.5957/ATTC-1995-005]Search in Google Scholar
[23. Maki K.J., Lee D., Troesch A.W., Vlahopoulos N.: Hydroelastic impact of a wedge-shaped body. Ocean Engineering 38, 2011, pp. 621–629.10.1016/j.oceaneng.2010.12.011]Open DOISearch in Google Scholar
[24. Mejri I., Bakir F., Rey R., Belamri T.: Comparison of computational results obtained from a homogeneous cavitation model with experimental investigations of three inducers, J. Fluids Eng.-Trans. ASME, 128, 2006, pp.1308–132310.1115/1.2353265]Search in Google Scholar
[25. Olofsson N.: A Contribution on the Performance of Partially Submerged Propellers, Proc. FAST ‘93, 2nd Intl. Conf. on Fast Sea Transportation. Yokohama, Japan, 1, 1993, pp. 765-776.]Search in Google Scholar
[26. Olofsson N.: Force and Flow Characteristics of a Partially Submerged Propeller, PhD Thesis, Department of Naval Architecture and Ocean Engineering, Chalmers Univ., Gotenborg, Sweden, 1996.]Search in Google Scholar
[27. Piro D.J., Maki K.J.: Hydroelastic Wedge Entry and Exit. 11th International Conference on Fast Sea Transportation FAST 2011, Honolulu, Hawaii, USA, September 2011.]Search in Google Scholar
[28. Piro D.J., Maki K.J.: Hydroelastic analysis of bodies that enter and exit water. Journal of Fluids and Structures 37, 2013, pp. 134–150.10.1016/j.jfluidstructs.2012.09.006]Search in Google Scholar
[29. Panciroli, R.: Water entry of flexible wedges: Some issues on the FSI phenomena. App. Ocean Res. 39, 2013, pp.72-74.10.1016/j.apor.2012.10.010]Search in Google Scholar
[30. Schnerr G.H., Sauer J.: Physical and numerical modeling of unsteady cavitation dynamics, in: Proceeding of 4th International Conference on Multiphase Flow, New Orleans, USA, 2001.]Search in Google Scholar
[31. Shademani, R., Ghadimi P.: Estimation of water entry forces, spray parameters and secondary impact of fixed width wedges at extreme angles using finite element based finite volume and volume of fluid methods. J. Brodogradnja 67(2), 2016, pp. 101-124.]Search in Google Scholar
[32. Shademani, R., P. Ghadimi.: Asymmetric Water Entry of Twin Wedges with Different Deadrises, Heel Angles, and Wedge Separations using Finite Element Based Finite Volume Method and VOF. Journal of Applied Fluid Mechanics, 10(1), 2017, pp. 353-368.10.18869/acadpub.jafm.73.238.26185]Search in Google Scholar
[33. Shademani R., Ghadimi P.: Numerical assessment of turbulence effect on forces, spray parameters, and secondary impact in wedge water entry problem using k-ε method, Scientia Iranica- B, 24(1), 2017, pp. 223-236.10.24200/sci.2017.4028]Open DOISearch in Google Scholar
[34. Singhal A.K., Athavale M.M., Li H., Jiang Y.: Mathematical basis and validation of the full cavitation model, J. Fluid Engineering, 124, 2002, pp. 617-624.10.1115/1.1486223]Search in Google Scholar
[35. Vinayan V., Kinnas S.A.: A numerical nonlinear analysis of two-dimensional ventilating entry of surface-piercing hydrofoils with effects of gravity, J. Fluid Mech. 658, 2010, pp. 383–408.10.1017/S0022112010001783]Search in Google Scholar
[36. Vinayan V. A Boundary Element Method for the Strongly Nonlinear Analysis of Ventilating Water-entry and Wave-body Interaction Problems. PhD thesis, Ocean Engineering Group, Architectural and Environmental Engineering, University of Texas at Austin, Austin, TX, USA, 2009.]Search in Google Scholar
[37. Wang D.P.: Water entry and exit of a fully ventilated foil, J. Ship Res. 21 (1), 1977, pp. 44–68.10.5957/jsr.1977.21.1.44]Search in Google Scholar
[38. Wang D.P.: Oblique water entry and exit of a fully ventilated foil, J. Ship Res, 23, 1979, pp. 43–54.10.5957/jsr.1979.23.1.43]Search in Google Scholar
[39. Wang G., Zhu X., Sheng Z.: Hydrodynamic forces of a three-dimensional fully ventilated foil entering water. J. Hydrodynamics, 5(2), 1990.]Search in Google Scholar
[40. Wu T.Y.: A Free-Streamline Theory for Two-Dimensional Fully Cavitated Hydrofoils, Mathematical Physics, 35, 1956, pp. 236–265.10.1002/sapm1956351236]Search in Google Scholar
[41. Yim B.: An application of linearized theory to water entry and water exit problems. Part 2 with ventilation, Rep. 3171. NSRDC, Washington, DC, USA. 1969.]Search in Google Scholar
[42. Yim B.: Linear theory on water entry and exit problems of a ventilating thin wedge, J. Ship Res. 18 (1), 1974, pp. 1–11.10.5957/jsr.1974.18.1.1]Search in Google Scholar
[43. Young Y.L.: Numerical modeling of supercavitating and surface-piercing propellers, PhD thesis, Ocean Engineering Group, Department of Civil ?, University of Texas at Austin, Austin, TX, USA, 2002.]Search in Google Scholar
[44. Young Y.L., Kinnas S.A.: Analysis of supercavitating and surface-piercing propeller flows via BEM, J. Computational Mechanics, 32, 2003, pp. 269-280.10.1007/s00466-003-0484-6]Search in Google Scholar
[45. Young Y.L., Savander B.R.: Numerical analysis of large-scale surface-piercing propellers. J. Ocean Engineering, 38, 2011, pp. 1368-1381.10.1016/j.oceaneng.2011.05.019]Search in Google Scholar
[46. Zwart P., Gerber A.G., Belamri T.: A Two-Phase Model for Predicting Cavitation Dynamics, ICMF International Conference on Multiphase Flow, Yokohama, Japan, 2004.]Search in Google Scholar
[47. Plik : PMR-2016-00084 : 43230 zn. norm. [24 str], stan 2018-01-16, kor. ang. epw]Search in Google Scholar