Team Name:  

Fluid-Solid-Acoustic Coupling Mechanics Research Team

Brief Introduction:

The Fluid-Solid-Acoustic Multi-field Coupling Mechanics Research team focused on major education and research center in fluid-solid-acoustic multiphysics coupling mechanical problems in China. It provides undergraduate to post graduate education in engineering mechanics. More than 20 students received their Master degrees in the last 5 years. The research activities in our team includes key research fields as follows:

l Fluid kinematics and dynamics

l Flow Induced Bibration

l Vibration and Acoustic

l Bio-inspired Metamaterial  

Our team has been working on fluid-solid-acoustic multi-field coupling mechanics challenges in engineering fields such as marine vessels, ocean engineering, hydraulic engineering, and biomechanics since 2019, has led over 10 national-level research projects and 20+ other scientific initiatives, with total funding exceeding 20 million yuan (RMB), published nearly 100 research papers, secured nearly 20 authorized national invention patents.The team The team faculty was composed of 2 professor and 3 vice professors as listed:

Team achievements

Research Area 1:  Fluid-structure coupling mechanism

1. Zhu Yue , Gan Jin , Lin Yongshui* ,et al. Graphics Processing Unit-Accelerated Propeller Computational Fluid Dynamics Using AmgX: Performance Analysis Across Mesh Types and Hardware Configurations[J]. Journal of Marine Science and Engineering, 2024, 12(12):2134.

2. Chen Wei, BaoYanxu , Lin Yongshui, Xiaoyu Zhang, et al. Flow-induced vibration of the drilling pipe with internal flow under the combination of control rods and rotation. Physics of Fluids, 2024,36(7):073603.

3. Du Aoyue, Chen Wei*, Yongshui Lin,et al. Vortex-induced vibration of a rotating cylinder with dual splitter plates. Physics of Fluids. 2024,36(8):083623.

4. Chen Wei, Du Aoyue , Lin Yongshui, et al. Investigation of vortex-induced vibrations of rotating cylinders with different surface roughness. Physics of Fluids,2024,36(4):043614.

5. Bao Yanxu, Zhang Xiaoyu, Lin Yongshui, et al. Investigation of coupled response on cylindrical eccentricity induced vibration and flow induced vibration. Ocean Engineering,2024, 305: 117978.

6. Geng Xinge, Wu Weiguo, Liu Erpeng, et al. Experimental Study on Vibration of a Rotating Pipe in Still Water and in Flow. Polish Maritime Research, 2023,30, 3923, 65-77.

7. Chen Wei, Bao Yanxu , Chai Wei *, et al. Investigation of the combined effect of control rods and forced rotation on a cylinder. Physics of Fluids,2023,35(10)：103605.

8. Bao Yanxu , Lin Yongshui, Chen Wei *, et al. Numerical investigation of wake and flow-induced vibration of a rotating cylinder in flow. Ocean Engineering, 2022,262:112207.

9. Zhao Xiaoyu, Wu Weiguo, Chen Wei, et al. Multi-network collaborative lift-drag ratio prediction and airfoil optimization based on residual network and generative adversarial network. Front Bioeng Biotechnol. 2022, 10:927064.

10.  Wang Siying, Wu Qibiao, Shi Xiaotao*. Numerical simulation and deep neural network revealed drag reduction of micro-structured three-dimensional square cylinders at high Reynolds numbers. Frontiers in Bioengineering and Biotechnology. 2022, 10:885962.

11. Chen Wei, Wang Siying, Shi Xiaotao*, et al. Numerical simulation of surface roughness effects on vortex-induced vibration of a circular cylinder at subcritical Reynolds number. International Journal of Naval Architecture and Ocean Engineering, 2022, 14:100430.

12. Liu Erpeng, Lin Yongshui, Chi Qingjia, et al. Numerical Investigation of Laminar Flow Past a Rotating Cylinder. Journal of Ship mechanics. 2022, 26(12): 1749-1761.

l Research Area 2: Vibration and Acoustic

1. Fan Bingbing, Lin Yongshui*, Liu Kai. Sound absorption design and characteristics of variable-section perforated double-porosity multiscale aerogel[J]. Journal of  Vibration AND Control, 2024,6.

2. Li Kangle, Zhou Zhiwei*, Huang Zhixin, Lin Yongshui* , et al. Underwater sound absorption characteristic of the rubber core sandwich structure with funnel-shaped cavities reinforced by carbon fiber columns. Applied acoustics, 2023, 188: 109375.

3. Hu Jinshun, Lin Yongshui, Zhou Zhiwei, et al. Study on the Low-Frequency and Broadband Sound Absorption Performance of an Underwater Anechoic Layer with Novel Design. Journal of Marine Science and Engineering, 2023, 11(2): 409.

4. Fan Bingbing, Xu Zhisun, Lin Yongshui*，et al. Mechanical properties of novel two-phase hybrid plate-lattice metamaterial. Mechanics of Advanced Materials and Structures. 2023, 30(23): 4752-4763.

5. Li Bangzheng, Huang Zhixin, Lin Yongshui*, et al. Mechanical properties of novel folded kirigami metamaterial under quasistatic compression. Smart materials and structures, 2022, 31(7): 075005.

6. Liu Bin, Yao Xinnan, Lin Yongshui *, et al. Experimental and numerical analysis of ultimate compressive strength of longspan stiffened panels. Ocean Engineering. 2021, 220: 108453

Research Area 3: Bio-inspired Metamaterial

1. Huang Zhenyang, Cao Xiaofei*, Niu Hu et al. Numerical and experimental evaluations on the defect sensitivity of the performance of BCC truss-lattice structures, Mechanics of Materials 2024 (191): 104937.

2. Yang Haoming, Zhang Yao, Wang Zhuangzhuang, Cao Xiaofei *, et al. Bioinspired dual-phase composite metamaterial for customized deformation behavior and performance characteristic, Materials Today Communications 2024 (38): 107655.

3. Yang Haoming, Cao Xiaofei*, Zhang Yao,  et al. 3D-printed bioinspired cage lattices with defect-tolerant mechanical properties, Additive Manufacturing 2024 (82): 104036.

4. Du Mingkun, Cao Xiaofei*, Lin Yongshui*, et al. Response of Topological Soliton lattice structures subjected to dynamic compression and blast loading[J]. Thin-Walled Structures, 2023, 188: 110858.

5. Deng Yun, Guo Xiaogang, Lin Yongshui, et al. Dual-Phase Inspired Soft Electronic Sensors with Programmable and Tunable Mechanical Properties. ACS nano, 2023, 17(7): 6423-6434.

6. Du Mingkun, Niu Hu, Wang Kaile,  Cao Xiaofei*, et al. Response of Topological Soliton lattice structures subjected to dynamic compression and blast loading, Thin-Walled Structures 2023 (188): 110858.

7. Wang Zhuangzhuang, Cao Xiaofei*, Zheng Qiuyao, et al. A novel strategy to improve the compressive characteristic and flexural stiffness of the metallic lattices by introducing the CFRP composite surfaces, Materials Today Communications 2023 (34): 105443.

PATENTS: