秦浩(Dr. Hao Qin),男,博士,副教授,硕士生导师,1990年生。长期致力于海洋科学、海洋工程与技术领域的教学和科研工作,重点开展深度学习和强化学习在海洋领域的应用、波浪与海工结构相互作用、畸形波及其载荷、海洋防灾减灾等方面的研究。主持、参与国家重点研发计划子课题、国家自然科学基金青年基金项目等科研项目10余项,发表各类论文30余篇,取得发明专利4项,获得省部级科技奖励2项。担任ISOPE国际会议分会场主席,担任Applied Science客座编辑,担任Ocean Engineering、Applied Ocean Research、Journal of Fluids and Structures、Ships and Offshore Structures等多个海洋工程领域重要期刊审稿人。
☆工作经历
►2021年8月—至今:beat365官方最新版,副教授;
►2019年9月—至今:智慧海洋信息技术湖北省工程研究中心,副主任;
►2019年5月—2022年10月:beat365官方最新版,海洋工程与技术系副系主任;
►2018年7月—2021年6月:beat365官方最新版,特任副教授;
☆教育经历
►2013年9月—2018年6月:上海交通大学,船舶与海洋工程专业(直接攻读博士),获博士学位;
►2009年9月—2013年6月:上海交通大学,船舶与海洋工程专业,获学士学位。
☆科研项目
[1] 国家重点研发计划子课题,海上遇险目标立体搜寻与高清晰观测关键技术——协同搜寻链条研究,2022-2025,主持;
[2] 国家重点研发计划课题,救捞作业关键数据协同监测与信息保障技术研究,2018-2021,参与;
[3] 国家自然科学基金青年基金,畸形波作用下考虑流固耦合效应的海洋平台结构动力响应研究,2022-2024,主持;
[4] 国家自然科学基金重点项目,畸形波的动力学机理及其对深海平台强非线性作用研究,2013-2017,参与;
[5] 深圳市自然科学基金基础研究项目(重点项目),基2020N117 气候变化背景下的全球与粤港澳大湾区海平面变化机理与上升趋势研究,2020-2023,主持;
[6] 广东省基础与应用基础研究基金项目,畸形波作用下考虑水弹性效应的海洋平台结构动力响应研究,2020-2022,主持;
[7] 南方海洋科学与工程广东省实验室(广州)人才团队引进重大专项,河口区海洋环境综合在线监测关键技术研究,2019-2022,参与;
[8] 中国地质大学(武汉)杰出人才培育基金,畸形波及其与海洋结构物相互作用数值模拟研究,2019-2021,主持。
[9] 福建省船舶与海洋工程重点实验室开放基金,畸形波作用下集装箱船运动响应及甲板上浪数值模拟研究,2022-2024,主持;
[10] 深圳市海洋监测预报中心项目,深圳海域海洋动力环境预报系统开发建设项目运维,2021-2021,主持;
[11] 中海油信息科技有限公司项目,新建港口船舶污染海洋环境风险评测及应急预案技术服务,2021-2022,主持。
[12] 广东省渔业捕捞和养殖业防灾减灾体系建设与维护专项,汕尾市渔业捕捞与养殖业防灾减灾体系建设与维护——重要渔港、重点增养殖区承灾体脆弱性调查与评估项目,2018-2019,主持;
[13] 广东省渔业捕捞和养殖业防灾减灾体系建设与维护专项,惠州市海洋与渔业局惠州市渔业捕捞与养殖业防灾减灾体系建设与维护项目,2018-2019,参与;
[14] 广东省渔业捕捞和养殖业防灾减灾体系建设与维护专项,江门市重要渔港、重点增养殖区承灾体调查及风险区划项目,2018-2019,参与;
☆发表论文
[1] Liang, H., Qin, H.*, Mu, L., Su, H., 2023. Real-time model for wave attenuation using active plate breakwater based on deep reinforcement learning. Ocean Engineering, in press. (师生合作)
[2] Wang, J., Qin, H.*, Hu, Z., Mu, L., 2023. Three-dimensional study on the interaction between a container ship and freak waves in beam sea. International Journal of Naval Architecture and Ocean Engineering, 15, 100509. (师生合作)
[3] Liang, H., Qin, H.*, Mu, L., 2023. Numerical study on an actively controlled flat plate breakwater. International Journal of Offshore and Polar Engineering, 33(01), 62-70. (师生合作)
[4] Qin, H., Wang, J., Zhao, E.*, Mu, L., 2022. Numerical study of rogue wave forces on flat decks based on the Peregrine breather solution under finite water depth. Journal of Fluids and Structures, 114, 103744.
[5] Wang, S., Mu, L., Qin, H.*, Wang, L., Yao, Z., Zhao, E., 2022. The utilization of physically based models and GIS techniques for comprehensive risk assessment of storm surge: A case study of Huizhou. Frontiers in Marine Science, 9, 939380.
[6] Liang, H., Zhao, E., Qin, H.*, Mu, L., Su, H., 2022. A model coupling CFD and DRL: investigation on wave dissipation by actively controlled flat plate. IEEE Access, 10, 98290-98308. (师生合作)
[7] Qin, H., Mu, L.*, Tang, W., Hu, Z., 2020. A concurrent multi-process refinement method applied in two-dimensional strong-coupled fluid-structure interaction problems. Ocean Engineering, 197, 106912.
[8] Qin, H., Mu, L.*, Tang, W., Hu, Z., 2019. Numerical study on structural response of anti-sloshing baffles of different configurations in a sloshing tank considering hydroelasticity. Ocean Engineering, 188, 106290.
[9] Qin, H., Mu, L.*, Tang, W., Hu, Z., 2019. Numerical study of the interaction between Peregrine breather based freak waves and twin-plate breakwater. Journal of Fluids and Structures, 87, 206-227.
[10] Qin, H., Tang, W.*, Xue, H., Hu, Z., Guo, J., 2017. Numerical study of wave impact on the deck-house caused by freak waves. Ocean Engineering, 133, 151-169.
[11] Qin, H., Tang, W.*, Hu, Z., Guo, J., 2017. Structural response of deck structures on the green water event caused by freak waves. Journal of Fluids and Structures, 68, 322-338.
[12] Qin, H., Tang, W.*, Xue, H., Hu, Z., 2017. Dynamic response of a horizontal plate dropping onto nonlinear freak waves using a fluid–structure interaction method. Journal of Fluids and Structures, 74, 291-305.
[13] Qin, H., Tang, W.*, Xue, H., Hu, Z., 2017. Numerical study of nonlinear freak wave impact underneath a fixed horizontal deck in 2-d space. Applied Ocean Research, 64, 155-168.
[14] Zhu, K., Jiang, R., Sun, Z., Qin, H., Cheng, Z., Wang, Y.*, Zhao, E., 2023. Numerical study on the effects of the multiple porous medium breakwaters on the propagation of the solitary wave. Journal of Marine Science and Engineering, 11(3), 565.
[15] Wu, Y., Zhu, K.*, Qin, H., Wang, Y., Sun, Z., Jiang, R., Wang, W., Yi, J., Wang, H., Zhao, E., 2023. Numerical investigation on the influence of breakwater and the sediment transport in Shantou offshore area. Applied Sciences, 13(5), 3011.
[16] Zhang, H., Tang, W.*, Wang, B., Qin, H., 2023. The occurrence probability prediction model of 2D and 3D freak waves generated by wave superposition. Ocean Engineering, 270, 113640.
[17] Zhang, H., Tang, W.*, Yuan, Y., Xue, H., Qin, H., 2022. The three-dimensional green-water event study on a fixed simplified wall-sided ship under freak waves. Ocean Engineering, 251, 111096.
[18] Zhang, Z., Pan, C., Zeng, J., Chen, F., Qin, H., He, K., Zhu, K., Zhao, E.*, 2022. Hydrodynamics of tidal bore overflow on the spur dike and its influence on the local scour. Ocean Engineering, 266, 113140.
[19] Zhang, H., Yuan, Y.*, Tang, W., Xue, H., Liu, J., Qin, H., 2021. Numerical analysis on three-dimensional green water events induced by freak waves. Ships and Offshore Structures, 16, 33-43.
[20] Hu, Z., Zhang, X.*, Li, Y., Li, X., Qin, H., 2021. Numerical simulations of super rogue waves in a numerical wave tank. Ocean Engineering, 229, 108929.
[21] Hu, Z., Zhang, X.*, Li, Y., Li, X., Qin, H., 2020. Numerical study on hydroelastic interaction between solitary wave and submerged box. Ocean Engineering, 205, 107299.
[22] Zhao, E., Mu, L.*, Qin, H., Jiang, H., 2019. Study on dynamic slope angle of sandy seabed around the submarine piggyback pipeline in steady flow. Journal of Marine Engineering and Technology, 1-13.
[23] Zhang, C., You, D., Qin, H.*, 2022. Numerical study on the bridge deck responses under solitary waves. The 32th International Ocean and Polar Engineering Conference, Shanghai, China. (师生合作)
[24] Wang, J., Qin, H.*, Mu, L., Li, Y., 2022. Numerical study on the ship motion responses under freak waves. The 32th International Ocean and Polar Engineering Conference, Shanghai, China. (师生合作)
[25] Liang, H., Qin, H.*, Mu, L., 2022. Numerical study on an actively controlled flat plate breakwater. The 32th International Ocean and Polar Engineering Conference, Shanghai, China. (师生合作)
[26] Yuan, X., Yao, Z., Qin, H.*, Mu, L., Jiang, H., 2020. Numerical study on the structural response of coastal bridge structures induced by tsunami wave forces based on CFD and FEM methods. The 30th International Ocean and Polar Engineering Conference, Shanghai, China. (师生合作)
[27] Qin, H.*, Mu, L., Zhao, E., 2019. Numerical study on the hydroelastic effects of the fluid-structure interaction in a sloshing tank with baffles. The 29th International Ocean and Polar Engineering Conference, Honolulu, Hawaii, USA.
[28] Qin, H., Xue, H.*, Tang, W., Liu, J., Hu, Z., 2017. Numerical simulation of the dynamic response of a beam structure impacted by nonlinear freak wave. The 27th International Ocean and Polar Engineering Conference, San Francisco, California, USA.
[29] 秦浩,唐文勇*,薛鸿祥.非线性畸形波所致的平台底部砰击载荷及结构响应数值模拟.上海交通大学学报(自然版), 2018, 52(9): 1009-1016.
[30] 秦浩,薛鸿祥*,唐文勇,扈喆.考虑水弹性效应的非线性畸形波甲板上浪砰击研究.第十八届中国海洋(岸)工程学术讨论会,中国舟山.
☆取得专利
[1] 发明专利,漂移速度预测方法、装置、计算设备及存储介质;
[2] 发明专利,风致漂移预测方法、装置、设备及存储介质;
[3] 发明专利,一种海上溢油的三维模拟方法及装置;
[4] 发明专利,一种海上搜救目标漂移预测方法及装置。
☆获得奖励
[1] 2019年,海洋科学技术奖一等奖,排名第三;
[2] 2019年,中国产学研合作创新成果奖一等奖,排名第三;
[3] 2017年,第十八届中国海洋(岸)工程学术讨论会青年优秀论文奖,排名第一;
☆竞赛指导
[1] 2022年,亚太地区大学生数学建模竞赛二等奖,指导教师(参赛学生:周鑫祎、陈浩生、夏凯);
[2] 2022年,第十九届五一数学建模竞赛一等奖,指导教师(参赛学生:周鑫祎、王培军、周均花);
[3] 2022年,数维杯大学生数学建模竞赛本科组三等奖,指导教师(参赛学生:周鑫祎、施皓程、王培军);
[4] 2022年,第八届中国国际“互联网+”大学生创新创业大赛国家级铜奖、省级金奖,参与指导(参赛学生:施皓程、周鑫祎、梁泽辉等)。
☆联系方式
通讯地址:湖北省武汉市洪山区鲁磨路388号中国地质大学beat365官方最新版。
电子邮箱:qinhao@cug.edu.cn.
☆招生意向
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