In Autonomous Underwater Vehicles (AUVs) design, hull resistance is an important factor in determining the power requirements and range of vehicle and consequently affect battery size, weight, and volume requirement of the design. In this paper, we leverage on AI-based optimization algorithm along with Computational Fluid Dynamics (CFD) simulation to study the optimal hull design that minimizing the resistance. By running the CFD-based optimization at different operating velocities and turbulence intensity, we want to study/search the possibility of a universal design that will provide least resistance/near-optimal design across all operating conditions (operating velocity) and environmental conditions (turbulence intensity). Early result demonstrated that the optimal design found at low velocity and low turbulence condition performs very poor at high velocity and high turbulence conditions. However, a design that is optimal at high velocity and high turbulence conditions performs near-optimal across many considered velocity and turbulence conditions.
翻译:在自动水下车辆(AUVs)设计中,船体阻力是确定车辆动力要求和范围的一个重要因素,从而影响到设计中的电池大小、重量和体积要求。在本文件中,我们利用基于AI的优化算法以及计算流体动力模拟(CFD)来研究最大限度减少阻力的最佳船体设计。通过在不同操作速度和动荡强度上运行基于CFD的优化,我们想研究/研究是否可能采用通用设计,在所有操作条件(操作速度)和环境条件(扰动强度)中提供最弱的抗力/最优化设计。早期结果显示,在低速度和低动荡状态下的最佳设计在高速和高震动条件下非常差。然而,在高速度和高震动条件下最优化的设计在很多考虑的速度和动荡条件下几乎最优化。