Time-domain TEBEM method for wave added resistance of ships with forward speed
A numerical method for solving 3D unsteady potential flow problem of ship advancing in waves was put forward. The flow field was divided into an inner and an outer domain by introducing an artificial matching surface. The inner domain was surrounded by a ship-wetted surface and a matching surface as...
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| Veröffentlicht in: | Journal of marine science and technology 2021-03, Vol.26 (1), p.174-189 |
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| creator | Duan, W. Y. Li, J. D. Chen, J. K. Ma, S. |
| description | A numerical method for solving 3D unsteady potential flow problem of ship advancing in waves was put forward. The flow field was divided into an inner and an outer domain by introducing an artificial matching surface. The inner domain was surrounded by a ship-wetted surface and a matching surface as well as part of the free surface. The free-surface condition for the inner domain was formulated by perturbation about the double-body (DB) flow assumption. The outer domain was surrounded by a matching surface and the rest had a free surface as well as an infinite far-field radiation boundary. The free-surface condition for the outer domain was formulated by perturbation of the uniform incoming flow. The simple Green function and transient free-surface Green function were used to form the boundary integral equation (BIE) for the inner and outer domains, respectively. The Taylor expansion boundary element method (TEBEM) was adopted to solve the DB flow and inner-domain and outer-domain unsteady flow BIE. Matching conditions for the inner-domain flow and outer-domain flow were enforced by the continuity of velocity potential and normal velocity on the matching surface. Direct pressure integration on the ship-wetted surface was applied to obtain the first- and second-order wave forces. The numerical prediction on the displacement, acceleration and added resistance of the 14000-TEU container ship at different forward speeds were investigated by the proposed TEBEM method. Reynolds-Averaged Navier–Stokes (RANS) equations based on Computational Fluid Dynamics (CFD) method were adopted to compare with TEBEM method. The physical tank experiment results also validated the accuracy of the numerical tank results. Compared with the experimental solutions, TEBEM obtained good agreement with the RANS CFD method. TEBEM, however, was much more efficient and robust. |
| doi_str_mv | 10.1007/s00773-020-00729-2 |
| format | Article |
| fullrecord | <record><control><sourceid>gale_webof</sourceid><recordid>TN_cdi_webofscience_primary_000532664300001CitationCount</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><galeid>A714875938</galeid><sourcerecordid>A714875938</sourcerecordid><originalsourceid>FETCH-LOGICAL-c358t-4f1dc625dfe5656c6dcad66df966397effc5e0d6681a23f75190e70ea2a8c9fd3</originalsourceid><addsrcrecordid>eNqNkE2PFCEQhonRxHH1D3gi8WhYi4-m6eM6mVWTVS_jmSAUO2y2mxEYJ_57WdvozRgSqFSep4CXkJccLjnA-Kb2bZQMBLBeiYmJR2TDlRyZEVw-JhuYlGFKGHhKntV6B8DHYYIN-bRPM7KQZ5cWut-93X2kM7ZDDjTmQs_uO1IXAgZasKba3OKR5kjrIR0rPad2eODOrgRaj4jhOXkS3X3FF7_PC_Llerffvmc3n9992F7dMC8H05iKPHgthhBx0IP2OngXtA5x0lpOI8boB4TeMdwJGceBT4AjoBPO-CkGeUFerXOPJX87YW32Lp_K0q-0Qk1SGSOF6tTlSt26e7RpibkV5_sKOCefF4yp969GrkxPQ5ouiFXwJddaMNpjSbMrPywH-xC0XYO2PWj7K2grumRW6Yxfc6w-YQ_pjwgAgxRaK9kr4NvUXEt52ebT0rr6-v_VTsuVrp1YbrH8_fQ_nvcT8xigiw</addsrcrecordid><sourcetype>Aggregation Database</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype><pqid>2493488324</pqid></control><display><type>article</type><title>Time-domain TEBEM method for wave added resistance of ships with forward speed</title><source>SpringerNature Journals</source><source>Web of Science - Science Citation Index Expanded - 2021<img src="https://exlibris-pub.s3.amazonaws.com/fromwos-v2.jpg" /></source><creator>Duan, W. Y. ; Li, J. D. ; Chen, J. K. ; Ma, S.</creator><creatorcontrib>Duan, W. Y. ; Li, J. D. ; Chen, J. K. ; Ma, S.</creatorcontrib><description>A numerical method for solving 3D unsteady potential flow problem of ship advancing in waves was put forward. The flow field was divided into an inner and an outer domain by introducing an artificial matching surface. The inner domain was surrounded by a ship-wetted surface and a matching surface as well as part of the free surface. The free-surface condition for the inner domain was formulated by perturbation about the double-body (DB) flow assumption. The outer domain was surrounded by a matching surface and the rest had a free surface as well as an infinite far-field radiation boundary. The free-surface condition for the outer domain was formulated by perturbation of the uniform incoming flow. The simple Green function and transient free-surface Green function were used to form the boundary integral equation (BIE) for the inner and outer domains, respectively. The Taylor expansion boundary element method (TEBEM) was adopted to solve the DB flow and inner-domain and outer-domain unsteady flow BIE. Matching conditions for the inner-domain flow and outer-domain flow were enforced by the continuity of velocity potential and normal velocity on the matching surface. Direct pressure integration on the ship-wetted surface was applied to obtain the first- and second-order wave forces. The numerical prediction on the displacement, acceleration and added resistance of the 14000-TEU container ship at different forward speeds were investigated by the proposed TEBEM method. Reynolds-Averaged Navier–Stokes (RANS) equations based on Computational Fluid Dynamics (CFD) method were adopted to compare with TEBEM method. The physical tank experiment results also validated the accuracy of the numerical tank results. Compared with the experimental solutions, TEBEM obtained good agreement with the RANS CFD method. TEBEM, however, was much more efficient and robust.</description><identifier>ISSN: 0948-4280</identifier><identifier>EISSN: 1437-8213</identifier><identifier>DOI: 10.1007/s00773-020-00729-2</identifier><language>eng</language><publisher>Tokyo: Springer Japan</publisher><subject>Acceleration ; Automotive Engineering ; Boundary element method ; Boundary integral method ; Cargo ships ; Computational fluid dynamics ; Computer applications ; Container ships ; Engineering ; Engineering Design ; Engineering Fluid Dynamics ; Engineering, Civil ; Engineering, Marine ; Far fields ; Fluid dynamics ; Free surfaces ; Green's function ; Green's functions ; Hydrodynamics ; Integral equations ; Mathematical models ; Mechanical Engineering ; Methods ; Numerical methods ; Numerical prediction ; Offshore Engineering ; Original Article ; Perturbation ; Potential flow ; Robustness (mathematics) ; Science & Technology ; Surface matching ; Taylor series ; Technology ; Three dimensional flow ; Time domain analysis ; Unsteady flow ; Velocity ; Velocity potential ; Wave forces ; Wave resistance</subject><ispartof>Journal of marine science and technology, 2021-03, Vol.26 (1), p.174-189</ispartof><rights>The Japan Society of Naval Architects and Ocean Engineers (JASNAOE) 2020</rights><rights>COPYRIGHT 2021 Springer</rights><rights>The Japan Society of Naval Architects and Ocean Engineers (JASNAOE) 2020.</rights><lds50>peer_reviewed</lds50><woscitedreferencessubscribed>true</woscitedreferencessubscribed><woscitedreferencescount>8</woscitedreferencescount><woscitedreferencesoriginalsourcerecordid>wos000532664300001</woscitedreferencesoriginalsourcerecordid><citedby>FETCH-LOGICAL-c358t-4f1dc625dfe5656c6dcad66df966397effc5e0d6681a23f75190e70ea2a8c9fd3</citedby><cites>FETCH-LOGICAL-c358t-4f1dc625dfe5656c6dcad66df966397effc5e0d6681a23f75190e70ea2a8c9fd3</cites></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktopdf>$$Uhttps://link.springer.com/content/pdf/10.1007/s00773-020-00729-2$$EPDF$$P50$$Gspringer$$H</linktopdf><linktohtml>$$Uhttps://link.springer.com/10.1007/s00773-020-00729-2$$EHTML$$P50$$Gspringer$$H</linktohtml><link.rule.ids>315,782,786,27933,27934,39267,41497,42566,51328</link.rule.ids></links><search><creatorcontrib>Duan, W. Y.</creatorcontrib><creatorcontrib>Li, J. D.</creatorcontrib><creatorcontrib>Chen, J. K.</creatorcontrib><creatorcontrib>Ma, S.</creatorcontrib><title>Time-domain TEBEM method for wave added resistance of ships with forward speed</title><title>Journal of marine science and technology</title><addtitle>J Mar Sci Technol</addtitle><addtitle>J MAR SCI TECH-JAPAN</addtitle><description>A numerical method for solving 3D unsteady potential flow problem of ship advancing in waves was put forward. The flow field was divided into an inner and an outer domain by introducing an artificial matching surface. The inner domain was surrounded by a ship-wetted surface and a matching surface as well as part of the free surface. The free-surface condition for the inner domain was formulated by perturbation about the double-body (DB) flow assumption. The outer domain was surrounded by a matching surface and the rest had a free surface as well as an infinite far-field radiation boundary. The free-surface condition for the outer domain was formulated by perturbation of the uniform incoming flow. The simple Green function and transient free-surface Green function were used to form the boundary integral equation (BIE) for the inner and outer domains, respectively. The Taylor expansion boundary element method (TEBEM) was adopted to solve the DB flow and inner-domain and outer-domain unsteady flow BIE. Matching conditions for the inner-domain flow and outer-domain flow were enforced by the continuity of velocity potential and normal velocity on the matching surface. Direct pressure integration on the ship-wetted surface was applied to obtain the first- and second-order wave forces. The numerical prediction on the displacement, acceleration and added resistance of the 14000-TEU container ship at different forward speeds were investigated by the proposed TEBEM method. Reynolds-Averaged Navier–Stokes (RANS) equations based on Computational Fluid Dynamics (CFD) method were adopted to compare with TEBEM method. The physical tank experiment results also validated the accuracy of the numerical tank results. Compared with the experimental solutions, TEBEM obtained good agreement with the RANS CFD method. TEBEM, however, was much more efficient and robust.</description><subject>Acceleration</subject><subject>Automotive Engineering</subject><subject>Boundary element method</subject><subject>Boundary integral method</subject><subject>Cargo ships</subject><subject>Computational fluid dynamics</subject><subject>Computer applications</subject><subject>Container ships</subject><subject>Engineering</subject><subject>Engineering Design</subject><subject>Engineering Fluid Dynamics</subject><subject>Engineering, Civil</subject><subject>Engineering, Marine</subject><subject>Far fields</subject><subject>Fluid dynamics</subject><subject>Free surfaces</subject><subject>Green's function</subject><subject>Green's functions</subject><subject>Hydrodynamics</subject><subject>Integral equations</subject><subject>Mathematical models</subject><subject>Mechanical Engineering</subject><subject>Methods</subject><subject>Numerical methods</subject><subject>Numerical prediction</subject><subject>Offshore Engineering</subject><subject>Original Article</subject><subject>Perturbation</subject><subject>Potential flow</subject><subject>Robustness (mathematics)</subject><subject>Science & Technology</subject><subject>Surface matching</subject><subject>Taylor series</subject><subject>Technology</subject><subject>Three dimensional flow</subject><subject>Time domain analysis</subject><subject>Unsteady flow</subject><subject>Velocity</subject><subject>Velocity potential</subject><subject>Wave forces</subject><subject>Wave resistance</subject><issn>0948-4280</issn><issn>1437-8213</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2021</creationdate><recordtype>article</recordtype><sourceid>HGBXW</sourceid><recordid>eNqNkE2PFCEQhonRxHH1D3gi8WhYi4-m6eM6mVWTVS_jmSAUO2y2mxEYJ_57WdvozRgSqFSep4CXkJccLjnA-Kb2bZQMBLBeiYmJR2TDlRyZEVw-JhuYlGFKGHhKntV6B8DHYYIN-bRPM7KQZ5cWut-93X2kM7ZDDjTmQs_uO1IXAgZasKba3OKR5kjrIR0rPad2eODOrgRaj4jhOXkS3X3FF7_PC_Llerffvmc3n9992F7dMC8H05iKPHgthhBx0IP2OngXtA5x0lpOI8boB4TeMdwJGceBT4AjoBPO-CkGeUFerXOPJX87YW32Lp_K0q-0Qk1SGSOF6tTlSt26e7RpibkV5_sKOCefF4yp969GrkxPQ5ouiFXwJddaMNpjSbMrPywH-xC0XYO2PWj7K2grumRW6Yxfc6w-YQ_pjwgAgxRaK9kr4NvUXEt52ebT0rr6-v_VTsuVrp1YbrH8_fQ_nvcT8xigiw</recordid><startdate>20210301</startdate><enddate>20210301</enddate><creator>Duan, W. 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Y.</au><au>Li, J. D.</au><au>Chen, J. K.</au><au>Ma, S.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Time-domain TEBEM method for wave added resistance of ships with forward speed</atitle><jtitle>Journal of marine science and technology</jtitle><stitle>J Mar Sci Technol</stitle><stitle>J MAR SCI TECH-JAPAN</stitle><date>2021-03-01</date><risdate>2021</risdate><volume>26</volume><issue>1</issue><spage>174</spage><epage>189</epage><pages>174-189</pages><issn>0948-4280</issn><eissn>1437-8213</eissn><abstract>A numerical method for solving 3D unsteady potential flow problem of ship advancing in waves was put forward. The flow field was divided into an inner and an outer domain by introducing an artificial matching surface. The inner domain was surrounded by a ship-wetted surface and a matching surface as well as part of the free surface. The free-surface condition for the inner domain was formulated by perturbation about the double-body (DB) flow assumption. The outer domain was surrounded by a matching surface and the rest had a free surface as well as an infinite far-field radiation boundary. The free-surface condition for the outer domain was formulated by perturbation of the uniform incoming flow. The simple Green function and transient free-surface Green function were used to form the boundary integral equation (BIE) for the inner and outer domains, respectively. The Taylor expansion boundary element method (TEBEM) was adopted to solve the DB flow and inner-domain and outer-domain unsteady flow BIE. Matching conditions for the inner-domain flow and outer-domain flow were enforced by the continuity of velocity potential and normal velocity on the matching surface. Direct pressure integration on the ship-wetted surface was applied to obtain the first- and second-order wave forces. The numerical prediction on the displacement, acceleration and added resistance of the 14000-TEU container ship at different forward speeds were investigated by the proposed TEBEM method. Reynolds-Averaged Navier–Stokes (RANS) equations based on Computational Fluid Dynamics (CFD) method were adopted to compare with TEBEM method. The physical tank experiment results also validated the accuracy of the numerical tank results. Compared with the experimental solutions, TEBEM obtained good agreement with the RANS CFD method. TEBEM, however, was much more efficient and robust.</abstract><cop>Tokyo</cop><pub>Springer Japan</pub><doi>10.1007/s00773-020-00729-2</doi><tpages>16</tpages></addata></record> |
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| subjects | Acceleration Automotive Engineering Boundary element method Boundary integral method Cargo ships Computational fluid dynamics Computer applications Container ships Engineering Engineering Design Engineering Fluid Dynamics Engineering, Civil Engineering, Marine Far fields Fluid dynamics Free surfaces Green's function Green's functions Hydrodynamics Integral equations Mathematical models Mechanical Engineering Methods Numerical methods Numerical prediction Offshore Engineering Original Article Perturbation Potential flow Robustness (mathematics) Science & Technology Surface matching Taylor series Technology Three dimensional flow Time domain analysis Unsteady flow Velocity Velocity potential Wave forces Wave resistance |
| title | Time-domain TEBEM method for wave added resistance of ships with forward speed |
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