Effects of Shape Changing of Morphing Rotary Wing Aircraft on Longitudinal and Lateral Flight

The Journal of aviation medicine Pub Date : 2022-08-02 DOI:10.30518/jav.1080139

Tuğrul Oktay, Enes Özen

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引用次数: 3

Abstract

Unmanned aerial vehicles are aerial robots controlled by commands sent from the ground control station. While fixed-wing aircraft have the advantages of long range and high altitude, they need a runway to create sufficient lift on the wings. The advantage of Rotary Wing Aircraft is that it does not need a runway, it can perform vertical take-off and landing. It can hover. Thanks to these features, it is used in tasks such as surveillance, search and rescue, and reconnaissance. In areas with chemical wastes or in closed environments without risking the human element; Desired tasks can be performed in places such as sewers, caves, and collapsed houses. For this, there is a flight control computer and software on the aircraft. Rotary-wing aircraft are more unstable than fixed-wing aircraft. Thanks to the flight controller, its stability and controllability are increased. In this study, a quadcopter, multicopter aircraft structure is used. The variation of the angle between the arms of a quadcopter aircraft and its effects on forward and sideways flight are examined. It is required that the aircraft be symmetrical in the longitudinal and lateral axis in order to cope with the disturbances to which it is exposed in external environments . In closed environments, atmospheric events are replaced by obstacles. One of the desirable features of the aircraft is that it can pass through narrow places. For this, the aircraft must perform a shape change. The change in structure will cause it to change in the dynamics equations, causing the rotors to react differently during linear and rotational movements of the aircraft. This study focuses on the system design and control of the aircraft. The geometric features obtained from the aircraft designed in the CATIA program were used in the creation of the mathematical model. The obtained values were created using the MATLAB Simulink program to create a digital twin of the aircraft. When the intersection angle between the arms is 90 degrees, the settling time of the 2-degree pitch angle is 7.48 seconds, and when it is 45 degrees, it is 10.3 seconds.

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变形旋翼飞机外形变化对纵向和横向飞行的影响

无人驾驶飞行器是由地面控制站发出的指令控制的空中机器人。虽然固定翼飞机具有航程远、海拔高的优点，但它们需要一条跑道来为机翼创造足够的升力。旋翼飞机的优点是不需要跑道，可以垂直起降。它可以悬停。由于这些特点，它被用于监视、搜救和侦察等任务。在有化学废物的地区或在没有人为因素危险的封闭环境中;可以在下水道、洞穴和倒塌的房屋等地方执行所需的任务。为此，飞机上有一个飞行控制计算机和软件。旋翼飞机比固定翼飞机更不稳定。由于安装了飞行控制器，提高了飞机的稳定性和可控性。本研究采用四旋翼、多旋翼飞行器结构。研究了四轴飞行器臂间夹角的变化及其对飞行器向前和侧向飞行的影响。要求飞机在纵向和横向轴上是对称的，以便应付它暴露在外部环境中的干扰。在封闭环境中，大气事件被障碍物所取代。这种飞机令人满意的特点之一是它能通过狭窄的地方。为此，飞机必须进行形状改变。结构的变化将导致动力学方程的变化，导致旋翼在飞机线性和旋转运动期间的反应不同。本文的研究重点是飞机的系统设计和控制。在CATIA程序中获得的飞机的几何特征被用于数学模型的创建。使用MATLAB Simulink程序创建得到的数值，以创建飞机的数字孪生。当两臂交角为90度时，2度俯仰角的沉降时间为7.48秒，当交角为45度时，沉降时间为10.3秒。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Journal of aviation medicine

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