Shiyu Li , Erke Qin , Rongjie Kang , Jian S. Dai , Zhibin Song
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引用次数: 0
Abstract
This paper proposes a novel underwater rotorcraft vehicle with a passively adjustable configuration based on a universal joint (URV-PAU), which addresses the issue of increased propeller load and control stability caused by the rigid structure of existing vehicles when tilted. Compared with designs that do not incorporate a U-joint structure, this vehicle can reduce energy consumption and enhance system manoeuvrability. First, a kinematic and dynamic model of the URV-PAU is established based on its configuration. Considering the nonlinearity of the system, the modelling errors of the dynamic model, and external disturbances, an adaptive backstepping sliding mode controller(ABSSMC) is designed to achieve motion control in proximity to the seabed. A prototype of the underwater rotorcraft vehicle was constructed according to the principles of modular design. Subsequently, underwater trajectory experiments were carried out within a water tank. The experiments demonstrated that the URV-PAU results in a reduction of approximately 10 % in system energy consumption and an improvement in system manoeuvrability compared with designs without a U-joint structure during motion at a constant depth.
本文提出了一种新型水下旋翼飞行器(URV-PAU),该飞行器采用基于万向节的被动可调结构,解决了现有飞行器倾斜时刚性结构导致螺旋桨负荷增加和控制稳定性的问题。与未采用 U 形关节结构的设计相比,该飞行器可降低能耗并提高系统的机动性。首先,根据 URV-PAU 的配置建立了其运动学和动力学模型。考虑到系统的非线性、动态模型的建模误差和外部干扰,设计了一种自适应反步进滑模控制器(ABSSMC),以实现在接近海底时的运动控制。根据模块化设计原则,建造了水下旋翼飞行器原型。随后,在水箱中进行了水下轨迹实验。实验结果表明,与没有 U 形接头结构的设计相比,URV-PAU 可在恒定深度运动时将系统能耗降低约 10%,并提高系统的机动性。
期刊介绍:
Mechanism and Machine Theory provides a medium of communication between engineers and scientists engaged in research and development within the fields of knowledge embraced by IFToMM, the International Federation for the Promotion of Mechanism and Machine Science, therefore affiliated with IFToMM as its official research journal.
The main topics are:
Design Theory and Methodology;
Haptics and Human-Machine-Interfaces;
Robotics, Mechatronics and Micro-Machines;
Mechanisms, Mechanical Transmissions and Machines;
Kinematics, Dynamics, and Control of Mechanical Systems;
Applications to Bioengineering and Molecular Chemistry