1、 著作
[1] 《海洋空间开发利用规划设计原理与方法》,王永学、任冰,科学出版社,2022
[2] 《海洋动力环境模拟数值算法及应用》,王永学、任冰,科学出版社,2019
2、期刊论文
[3] Zhu G, Ren B.*, Lin P, Dong P.. Numerical study of wave-induced flow and wave set-up on a platform reef with steep slope. Applied Ocean Research, 2024, 148: 104030.
[4] Wang C, Lin P, Ren B.*. A numerical model for simulation of two-phase flows interaction with flexible slender bodies. Physics of Fluids, 2023, 35(12).
[5] Chen W, Wang C, Ren B.*, Lin P.. Experimental study of the motion characteristics of a twin-circular submerged floating tunnel under wave actions. Ocean Engineering, 2023, 288: 116114.
[6] Zhao H, Ding H, Wang C, Li K, Wang G, Ren B.. Vortex-induced vibration at low Reynolds numbers: Vortex shedding modes transitions. Ocean Engineering, 2023, 288: 115931.
[7] Zhu J.,Ren B.*, Dong P., Chen W., Wang Y., Natural vibration characteristics of short-span submarine power cables with bending stiffness and sag. Marine Structures, 103328 (2023).
[8] Zhu J., Ren B.*, Dong P., Chen W., Vortex-induced vibrations of a free spanning submarine power cable. Ocean Engineering, 113792 (2023).
[9] Wang C., Ren B.*, Lin P., A coupled flow and beam model for fluid–slender body interaction. Journal of Fluids and Structures, 2022, 115: 103781.
[10] Zhu G., Ren B.*, Dong, P., Wang, Y., Chen, W., Experimental investigation on the infragravity wave on different reef systems under irregular wave action. Ocean Engineering, 226(C2): 108851(2021).
[11] Wen H., Ren B.*, Dong P., Zhu G., Numerical analysis of wave-induced current within the inhomogeneous coral reef using a refined SPH model. Coastal Engineering 156: 103616(2020).
[12] Chen J., Wen H.*, Wang Y., Ren B., Experimental investigation of an annular sector OWC device incorporated into a dual cylindrical caisson breakwater. Energy, 2020, 211: 118681.
[13] Wen H., Ren B.*, Zhu G., Wang G., SPH evaluation of the hydrodynamic consequence induced by reef degradation, Wave Motion 96(2020) 102579, 1-20
[14] Zhu G., Ren B.*, Wen H., Wang Y., Wang C., Analytical study of wave setup over permeable coral reef. Applied Ocean Research, 90(2019):101859.
[15] Wen H., Ren B.*, Zhang X., Yu X., SPH modeling of wave transformation over a coral reef with seawall. Journal of Waterway Port Coastal and Ocean Engineering-ASCE, 2019, 145(1):04018026.
[16] Wen H., Ren B.*, Yu X., An improved SPH model for turbulent hydrodynamics of a 2D oscillating. Ocean Engineering, 150(2018): 152-166.
[17] Wen H., Ren B.*, Wang G., 3D SPH porous flow model for wave interaction with permeable structures. Applied Ocean Research, 75(2018):223-233.
[18] Wen H., Ren B.*. A Non-Reflective spectral wave maker for SPH modeling of nonlinear wave motion. Wave Motion, 2018, 79:112-128
[19] Guo W., Jiang M., Li X., Ren B.*, Using a genetic algorithm to improve oil spill prediction. Marin Pollution Bulletin, 2018, 135, 386-396.
[20] Wen H., Ren B.*, Wang G., Zhao Y., Numerical simulation of wave breaking over a submerged step with SPH method. International Journal of Ocean and Coastal Engineering, 2 (2018) 1840005.
[21] He, M., Xu, W.*, Gao, X., Ren B., SPH simulation of wave scattering by a heaving submerged horizontal plate. International Journal of Ocean and Coastal Engineering, 2 (2018) 1840004.
[22] He, M., Xu, W.*, Gao, X., Ren B., The layout of submerged horizontal plate breakwater (SHPB) with respect to the tidal-level variation. Coast Engineering Journal, 2018, 60(3): 280-298.
[23] Ren B.*, He M., Li Y.,Wen H., Application of smoothed particle hydrodynamics for modeling the wave-moored floating breakwater interaction. Applied Ocean Research, 67(2017):277–290.
[24] Wang G., Ren B.*, Wang Y., Experimental study on hydrodynamic performance of arc plate breakwater. Ocean Engineering,111(2016):593-601.
[25] Ren B.*, Wen H., Dong P., Wang Y., Improved SPH simulation of wave motions and turbulent flows through porous media. Coastal Engineering, 107 (2016), 14-27.
[26] Wen H., Ren B.*, Dong P., Wang Y., A SPH numerical wave basin for modelling wave-structure interactions, Applied Ocean Research, 59(2016): 366–377.
[27] Ren B.*, He M., Dong P., Wen H., Nonlinear simulations of wave-induced motions of a freely floating body using WCSPH method. Applied Ocean Research, 50(2015): 1-12.
[28] Jiang M., Ren B.*, Wang G., Laboratory study on the hydrodynamic and structural characteristic of violent sloshing in elastic tanks. Ships and Offshore Structures, 2015,10(5),533-544.
[29] Jiang M., Ren B.*, Wang G., Laboratory study on the hydrodynamic and structural characteristic of violent sloshing in elastic tanks. Ships and Offshore Structures, 2015,10(5),533-544.
[30] Ren B.*, Wen H., Dong P., Wang Y., Numerical simulation of wave interaction with porous structures using an improved smoothed particle hydrodynamic method. Coastal Engineering, 88(2014): 88-10
[31] Ren B.*, Jin Z., Gao R., Wang Y., Xu Z., SPH-DEM modeling of the hydraulic stability of 2D blocks on a slope. Journal of Waterway, Port, Coastal, and Ocean Engineering-ASCE, 2014, 140(6), 04014022: 1-12.
[32] Gao R., Ren B.*, Wang G., Wang Y., Numerical modelling of regular wave slamming on subface of open-piled structures with the SPH method. Applied Ocean Research, 34(2012): 173-186
[33] Ding Z., Ren B.*, Wang Y., Ren X., Experimental study of unidirectional irregular wave slamming on the threedimensional structure in the splashzone. Ocean Engineering, 2008, 35(16): 1637-1646.
[34] Ren B.*, Wang Y., Laboratory study of random wave slamming on a piled wharf with different shore connecting structures. Coastal Engineering, 52(2005): 463-471.
[35] Ren B.*, Wang Y., Numerical simulation of random wave slamming on the structure in the splash zone. Ocean Engineering, 2004, 31(5-6): 547-560.
[36] Zhang H., Wang Y., Ren B., Application of neural network on wave impact force prediction. International Symposium on Neural Networks (ISSN 2004),2004.08,Advances in Neural Networks, PT 2: 854-859.
[37] Ren B.*, Wang Y., Experimental study of irregular wave impact on the structures in splash zone. Ocean Engineering, 2003, 30(18): 2363-2377.
[38] 赵海栋,王超,任冰,陈卫东,王国玉. 基于 FDM-VBF 的低雷诺数串列双圆柱绕流数值模拟. 大连理工大学学报, 2022, 63 (3): 292-298.
[39] 赵宇蒙, 温鸿杰, 任冰*, 王超. 低雷诺数下圆柱强迫振动特性光滑粒子流体动力学模拟. 海洋工程, 2021, 39(4): 134-143.
[40] 王超,秦世杰,于明,任冰*. 长周期波作用下透空式防波堤的防浪性能研究, 港工技术, 2019, 56: 20-24.
[41] 温鸿杰,张向,任冰*,王永学,规则波在岛礁地形上传播的 SPH 模拟,科学通报, 2018, 63(9): 865-874.
[42] 任冰*,唐洁,王国玉,朱干城,规则波在岛礁地形上传播变化特性的试验,科学通报,2018, 63:5~6,590-600
[43] 朱干城,任冰*,王永学,邱大洪,直墙结构物对台礁礁坪上规则波传播特性的影响,中国科学:技术科学,2018, 48, 1-11.
[44] 温鸿杰,张向,任冰*,王国玉,随机波在珊瑚礁地形上传播变形的 SPH 模拟,水动力学研究与进展,2018.11,Vol.33, No.6, 706-713.
[45] Ren B.*, Liu M., Li X., Wang Y., Experimental Investigation of Wave Slamming on An Open Structure Supported Elastically, China Ocean Engineering 30(2016), No.6: 967-978.
[46] He M., Ren B.*, Qiu D., 2016. Experimental study of nonlinear behaviors of a free-floating body in waves. China Ocean Engineering, 30(3):421-430.
[47] 任冰*, 李晨光, 蒋梅荣, 王国玉,王永学. 弹性变形对三维弹性液箱内晃荡波面的影响. 科学通报, 2016, 61(4-5): 543-552.
[48] 刘明,任冰*,支撑刚度对水平板波浪冲击压力影响,海洋工程,2015,33(5),42-50.
[49] Jiang M., Ren B.*, Wang G., Wang Y., Laboratory investigation of the hydroelastic effect on liquid sloshing in rectangular tanks. Journal of Hydrodynamics, Ser. B, 2014, 26(5): 751-761.
[50] 崔焱, 姜峰, 任冰*. 波浪作用下斜坡上护面块体内部应力分布数值模拟. 海洋工程, 2014, 32(5): 78-84.
[51] 宋子路, 任冰*, 孙见峰, 刘明, 王国玉. 弹性支撑水平板上的波浪冲击压力试验研究. 水动力学研究与进展, 2014, 29(4): 435-443.
[52] 蒋梅荣, 任冰*, 李小超, 王永学. 有限液深下弹性侧壁液舱内晃荡共振特性实验研究. 大理工大学学报, 2014, 54(5): 558-567.
[53] 孙见峰, 任冰*, 宋子路, 王永学. 波浪对弹性支撑结构物冲击作用试验研究. 大连理工大学学报, 2014, 54(2): 222-227.
[54] 蒋梅荣, 任冰*, 温鸿杰, 王永学. 弹性液舱内液体晃荡实验研究. 海洋工程, 2013, 31(5): 1-10.
[55] 任冰*, 金钊, 高睿, 贺铭, 王永学. 波浪与斜坡堤护面块体相互作用的 SPH-DEM 数值模拟. 大连理工大学学报, 2013, 53(2): 241-248.
[56] 任冰*, 叶晓文, 高睿, 王国玉, 王永学. 波浪与多孔介质结构相互作用的 SPH 模拟. 海洋工程, 2012, 30(2): 46-53.
[57] 任冰*, 高睿, 金钊, 王国玉, 王永学. 波浪对透空式结构物冲击作用的光滑粒子流体动力学数值模拟. 海洋学报, 2012, 34(1): 163-177.
[58] 张秋艳, 任冰*, 蒋梅荣. 二维矩形弹性液舱内液体晃荡数值模拟研究. 船海工程, 2012, 41(4): 11-20.
[59] 李雪艳, 任冰*, 王国玉, 王永学. 基于 BFC-VOF 方法的弧形防浪墙水动力数值模拟. 水道港口, 2011, 32(4): 270-275.
[60] Ding Z., Wang G.*, Ren B., Three-dimensional numerical simulation of wave slamming on an open structure. Journal of Hydrodynamics, 2012, 24(4):526-534.
[61] Li X., Ren B.*, Wang G., Wang Y., Numerical simulation of hydrodynamic characteristic on arc crown wall using VOF method based on BFC. Journal of Hydrodynamics, 2011, 23(6): 767-776.
[62] 郭保臣, 任冰*, 刘明. 波浪冲击作用下海洋结构物的动力响应. 水道港口, 2011, 32(3): 168-172.
[63] 任冰*, 李雪艳, 王永学. 基于贴体网格的 VOF 方法数模流场研究. 计算力学学报, 2011, 28(6): 872-878.
[64] 高睿, 任冰*, 王国玉, 王永学. 孤立波浅化过程的 SPH 数值模拟. 水动力学研究与进展, A 辑, 2010, 25(5): 620-629.
[65] 韩朋, 任冰*, 李雪临, 王永学. 基于 VOF 方法的不规则波数值浪水槽的阻尼消波研究. 水道港口, 2009, 30(1): 9-13.
[66] Ren B.*, Li X., Wang Y., An irregular wave maker of active absorption with VOF method. China Ocean Engineering, 2008.12, 22, 4, 1-12.
[67] 丁兆强, 任冰*, 王永学, 任效忠, 随机波浪对浪溅区三维结构物冲击作用, 大连理工大学学报, 2008.11, 48(6):904-911.
[68] Ren B.*, Li X., Wang Y., Experimental investigation of the instantaneous properties of wave slamming on the plate. China Ocean Engineering, 2007, 21(3): 533-540.
[69] 任冰*, 李雪临, 王永学. 波浪冲击过程流场变化特性实验研究. 海洋工程, 2006, 24(4): 68-74.
[70] 黄小华, 王永学, 任冰. 波浪变态模型试验变率影响的计算机仿真研究, 中国造船, 2005, 46(增刊): 153-161.
[71] Ren B.*, Wang Y. Impact pressure of incident regular waves and irregular waves on the surface of open-piled structures. China Ocean Engineering, 2004, 18(1): 35-46.
[72] 张红玉, 王永学, 任冰. 人工神经网络在计算波浪冲击力中的应用, 中国造船, 2004, 45(增刊): 110-116.
[73] 任冰*, 王永学. 不规则波对浪溅区结构物冲击作用的试验研究频域分析. 海洋工程, 2003, 21(4): 53-60.
[74] 任冰*, 王永学. 不规则波对透空式建筑物上部结构冲击作用时域分析. 大连理工大学学报, 2003, 43(6):818-824.
[75] 任冰*, 王永学. 非线性波浪对结构物的冲击作用. 大连理工大学学报, 1999, 39(4): 562-566.
[76] 王永学, 任冰*. 波浪冲击过程的湍流数值模拟. 水动力学研究与进展, A 辑, 1999, 14(4): 409-417.
3、会议论文
[1] Chen W., Zhao H., Chen J., Ren B.*, Laboratory tests on the motion characteristic of truncated submerged floating tunnel considering boundary stiffness under the regular wave action. The 14th International Conference on Hydrodynamics, 2022, Wuxi, China.
[2] Zhu G., Ren B.*, Wang Y., Wang C., Experimental research of wave transformation on porous coral reef. OMAE2019-96582. June 9-14, 2019, Glasgow, Scotland.
[3] Zhu G., Xia Y., Ren B.*, Wang G., The Influence of Vertical-wall Structure on Monochromatic Wave Propagation Characteristics over the Deep-sea Coral Reefs, Sapporo, ISOPE 2018, Japan, June 10-15, 2018.
[4] Zhang X., Ren B.*, Wang Y., Wen H., Numerical simulation of wave transformation over deep-sea platform reef using SPH method, OMAE 2018-77325, June 17-22, 2018, Madrid, Spain.
[5] 温鸿杰,张向,任冰*,王国玉,随机波在珊瑚礁地形上传播变形的 SPH 模拟,第 29 届全国水动力学研讨会,浙江舟山,2018.8.
[6] Li Y., He Ming, Ren B.*, Wang G., Numerical simulation of wave interaction with a hinged multi-module floating structures, OMAE 2017-61079, June 25-30, 2017, Trondheim, Norway.
[7] Ren B.*, Chen C., Dong P., Li Y., SPH modeling of wave interaction with partially perforated caissons. Proceedings of the Twenty-sixth (2016) International Ocean and Polar Engineering Conference, Rhodes, Greece, June 26-July 1, 2016, 198-205.
[8] Tang J, Ren B.*, Wang G., Experimental investigation of the Three-dimensional sloshing in a square-base tank with elasticity. Proceedings of the Twelfth (2016) Pacific-Asia Offshore Mechanics Symposium, Gold Coast, Australia, October 4-7, 2016, 205-212.
[9] Chen C., Ren B.*, Wen Hongjie, Numerical simulation of wave interaction with perforated caissons using SPH. Meshfree Methods in Computational Hydraulics, 2016, 33-50.
[10] Li C., Jiang M., Ren B.*, Wang Y.,Experimental investigation into the effects of fluid-structure interaction on the sloshing waves in 3D elastic tanks. Proceeding of 36th IAHR World Congress. IAHR 2015, 28 June–3 July, 2015, The Hague, the Netherlands.
[11] 任冰*,温鸿杰,王永学,王国玉(2015),波浪与抛石堤相互作用的湍流模拟,第十七届中国海洋(岸)工程学术讨论会论文集(上),2015,P483-488,南宁,中国.
[12] Wen H., Ren B.*, 3D numerical wave basin based on parallelized SPH method. OMAE 2014, June 8-13, 2014, San Francisco, California, USA.
[13] Jiang M., Ren B.*, Wang G., Wang Y., Laboratory study on the hydrodynamic and structural characteristic of violent sloshing in elastic tanks. The 7th International Conference on the Thin-Walled Structures, Sep.28-Oct. 2, 2014, Busan, Korea, ICTWS2014-0801: 1-10.
[14] He M., Ren B.*, Jiang F., Ma C., Simulation of dynamic coupling between waves and a free-floating rectangular box by smoothed particle hydrodynamics. OMAE2013, June 9-14, 2013, Nantes, France, OMAE2013-10286.
[15] 金钊, 任冰*, 徐志林, 王国玉. 基于 SPH 并行算法的数值波浪水槽研究. 第 24 届全国水动力学研讨会文集, 332-339, 2012 年, 江苏无锡.
[16] Cheng X., Wang Y.*, Ren B., Wang G., Numerical study of hydrodynamic forces on a submarine piggyback pipeline under wave action. The 31st International Conference on Ocean, Offshore and Arctic Engineering, July 1-6, 2012, Rio de Janeiro, Brazil, OMAE2012-83214.
[17] Gao R., Ren B.*, Wang G., Wang Y., SPH Model of Solitary Waves Shoaling on a Mild Sloping Beach, Proceedings of the Twentieth International Offshore and Polar Engineering Conference, Beijing, China, June 20 25, 2010. 590-595.
[18] Li X., Ren B.*, Wang Y., Numerical study of the irregular wave impact. The 19th International Offshore and Polar Engineering Conference, 510-517, Osaka, Japan, June 21-26, 2009.
[19] Ren B.*, Li X., Han P., Wang Y., Numerical non-reflecting irregular wave flume based on VOF method. The ASME 2009 28th International Conference on Ocean, Offshore and Arctic Engineering.OMAE2009, May 31 -June 5, 2009, Honolulu, Hawaii, USA, OMAE2009-79206.
[20] Ding Z., Ren B.*, Wang Y., Spectral analysis of unidirectional wave slamming on the three-dimensional structures in the splash zone. The 19th International Offshore and Polar Engineering Conference, 1024-1030, Osaka, Japan, June 21-26, 2009.
[21] 高睿, 任冰*. 波浪沿斜坡传播的 SPH 数值模拟. 第十四届中国海洋(岸)工程学术讨论会论文集, 482-487, 呼和浩特, 2009.8.
[22] Ren B.*, Ding Z., Wang Y. Experimental study of regular wave impact on the three-dimensional structure in the splash zone. The 17th International Offshore and Polar Engineering Conference, 2007, 3623-3629.(EI 收录)
[23] 丁兆强, 任冰*, 王永学, 任效忠. 单向波对浪溅区三维结构物冲击作用的研究. 第十三届中国海洋工程学术讨论会论文集, 2007, 176-184.
[24] 李雪临, 任冰*, 王永学. VOF 方法中主动吸收式无反射数值造波研究. 第 24 全国水动力学研讨会文集, 2007, 265-272.
[25] Ren B.*, Wang Y., Experimental study of irregular wave impact on piled wharf with permeable slope shore connecting. APAC2003, Japan, 2004, 177-178.
[26] 任冰*, 王永学. 随机波浪对不同接岸型式码头上部结构的冲击作用研究. 第 18 届全国水动力学研讨会文集, 新疆乌鲁木齐, 2004 .08, 481-492.
[27] 任冰*, 王永学. 随机波浪对透空式建筑物上部结构冲击作用的数值模拟. 第十一届中国海岸工程学术讨论会暨 2003 年海峡两岸港口及海岸开发研讨会论文集, 海南三亚, 2003, 195-204.
[28] Wang Y., Ren B.*. Experimental study of Irregular Wave slamming. ISOPE, Kitakyushu, Japan, 2002, 492-495.
[29] Ren B.*, Wang Y., Spectral analysis of irregular wave impact on the structure in splash zone. OMAE, Oslo, Norway, 2002, OMAE2002-28091.
[30] Ren B.*, Wang Y., Kassels Seth. Experimental investigation of wave impact on piled wharves with different shore connecting structure. APAC, Dalian, China, 2001, 751-757.
[31] 任冰*, 王永学. 波浪对不同接岸型式桩基码头冲击作用的实验研究. 第五届全国水动力学学术会暨第十五届全国水动力学研讨会论文集, 武汉, 2001, 150-157.
[32] Wang Y., Liu M., Ren B., Experimental study of wave slamming. OMAE’98, Lisbon, Portugal, 1998, OMAE98-0403.
[33] Wang Y., Ren B.*. Numerical simulation of wave slamming by turbulent model. Pacific Conference on Ocean Science and Technology, Hong Kong, China, 1997, 251-259.
