Numerical calculation of DTMB5415 ship model with three different depth interceptors were carried out based on RANS(Reynolds-averaged Navier-Stokes) method in order to study the influence of interceptors on the ship resistance and wake field. The hydrodynamic performance of the ship with and without interceptor was analyzed in detail. Meanwhile, the variation of stern waveform, the hull pressure and the axial flow field were discussed. The results shown that the installation of interceptor could reduce the resistance of DTMB5415, and the average drag reduction rate could reach 4.19%. The increase of the virtual length of the hull and the improvement of the tail flow field of the transom stern ship reduced the wave making resistance, which was the main reason for the decrease of the total resistance. The existence of interceptor increased the boundary layer thickness at the ship stern and the axial nominal wake, meanwhile, the average wake fraction at the propeller disk increased by 11.9% when Fr=0.35 and d/LPP=0.0015, where Fr is Froude rumber, d is the depth of the spoiler and LPP is the length of the ship.
SONG Kewei,GUO Chunyu,GONG Jie,LI Ping,WANG Wei
. Numerical Study on the Effect of Interceptors on the Resistance and
Wake Field of Twin-Screw Ship[J]. Journal of Shanghai Jiaotong University, 2019
, 53(8)
: 957
-964
.
DOI: 10.16183/j.cnki.jsjtu.2019.08.010
[1]AMACHER R, LIECHTI T C, PFISTER M, et al. Wave-reducing stern flap on ship convoys to protect riverbanks[J]. Naval Engineers Journal, 2015, 127(1): 95-102.
[2]蒋一, 孙寒冰, 邹劲, 等. 变角度尾压浪板对断级滑行艇阻力性能的影响[J]. 上海交通大学学报, 2017, 51(3): 320-325.
JIANG Yi, SUN Hanbing, ZOU Jin, et al. Influence of angle-variable stern flap on resistance performance of stepped planing hull[J]. Journal of Shanghai Jiao Tong University, 2017, 51(3): 320-325.
[3]KIM D H, SEO I D, RHEE K P, et al. A model test study on the effect of the stern interceptor for the reduction of the resistance and trim angle for wave-piercing hulls[J]. Journal of the Society of Naval Architects of Korea, 2015, 52(6): 485-493.
[4]KARAFIATH G. The effect of stern wedges on ship powering performance[J]. Naval Engineers Journal, 1987, 99(3): 27-38.
[5]邓锐, 黄德波, 周广利, 等. 阻流板水动力机理的初步计算研究[J]. 船舶力学, 2012, 16(7): 740-749.
DENG Rui, HUANG Debo, ZHOU Guangli, et al. Preliminary numerical research of the hydrodynamic mechanism of interceptor[J]. Journal of Ship Mechanics, 2012, 16(7): 740-749.
[6]MANSOORI M, FERNANDES A C. Hydrodyna-mics of the interceptor on a 2-D flat plate by CFD and experiments[J]. Journal of Hydrodynamics, 2015, 27(6): 919-933.
[7]GHASSEMI H, MANSOURI M, ZAFERANLOUEI S. Interceptor hydrodynamic analysis for handling trim control problems in the high-speed crafts[J]. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2011, 225(11): 2597-2618.
[8]MANSOORI M, FERNANDES A C. The interceptor hydrodynamic analysis for controlling the porpoising instability in high speed crafts[J]. Applied Ocean Research, 2016, 57: 40-51.
[9]MANSOORI M, FERNANDES A C. Interceptor and trim tab combination to prevent interceptor’s unfit effects[J]. Ocean Engineering, 2017, 134: 140-156.
[10]黄胜, 单铁兵. 附体对船尾伴流场的影响研究[J]. 哈尔滨工程大学学报, 2008, 29(11): 1147-1153.
HUANG Sheng, SHAN Tiebing. The effects of appendages on ship’s wakes[J]. Journal of Harbin Engineering University, 2008, 29(11): 1147-1153.
[11]王展智, 熊鹰, 刘志华, 等. 双臂轴支架的剖面形状和安装角度对船舶伴流场的影响[J]. 中国舰船研究, 2012, 07(4): 23-29.
WANG Zhanzhi, XIONG Ying, LIU Zhihua, et al. Effects of twin shaft bracket section profile and installation angle on nominal wake field [J]. Chinese Journal of Ship Research, 2012, 07(4): 23-29.
[12]王展智, 熊鹰, 孙海涛, 等. 双桨船附体阻力尺度效应[J]. 上海交通大学学报, 2015, 49(2): 255-261.
WANG Zhanzhi, XIONG Ying, SUN Haitao, et al. Scale effect of appendage resistance of twin-screw ship[J]. Journal of Shanghai Jiao Tong University, 2015, 49(2): 255-261.
[13]OLIVIERI A, PISTANI F, AVANZINI A, et al. Towing tank experiments of resistance, sinkage and trim, boundary layer, wake, and free surface flow around a naval combatant INSEAN 2340 model[D]. Iowa City: The University of Iowa, 2001.
[14]GUI L, LONGO J, STERN F. Towing tank PIV measurement system, data and uncertainty assessment for DTMB Model 5512[J]. Experiments in Fluids, 2001, 31(3): 336-346.
[15]MANSOORI M, FERNANDES A C. Hydrodynamics of the interceptor analysis via both ultra-reduced model test and dynamic CFD simulation[J]. Journal of Offshore Mechanics & Arctic Engineering, 2017, 139(2): 0211101.
[16]REICHARDT. Vollstndige Darstellung der turbulenten Geschwindigkeitsverteilung in glatten Leitungen[J]. Zamm-Journal of Applied Mathematics & Mechanics, 1951, 31(7): 208-219.
[17]LARSSON L, STERN F, VISONNEAU M. CFD in ship hydrodynamics—Results of the Gothenburg 2010 workshop[C]//MARINE 2011, IV International Conference on Computational Methods in Marine Engineering. Dordrecht: Springer, 2013: 237-259.
