The Design of a Lightweight Cable Aerial Manipulator with a CoG Compensation Mechanism for Construction Inspection Purposes

AlAkhras, Ayham; Sattar, Ilham Hassan; Alvi, Muhammad; Qanbar, Mohammed W.; Jaradat, Mohammad A.; Alkaddour, Muhannad

doi:10.3390/app12031173

Cited by 15 publications

(12 citation statements)

References 20 publications

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“…The value of the joint angle η 1 is derived using equations ( 22) and (23). Expanding the two equations and substituting d 2 sin η 2 = k 1 and…”

Section: Mathematical Preliminariesmentioning

confidence: 99%

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Effect of constraints and vertical wall interaction on workspace of a quadcopter manipulator system

Sumathy,

Warier,

Ghose

2023

Proceedings of the Institution of Mechanical Engineers, Part G:

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The workspace analysis of a robotic arm coupled to an unmanned aerial vehicle executing close-to-target operations is significant. The workspace of a 3 degree-of-freedom manipulator mounted to the bottom of a quadcopter and having an extended workspace is analyzed in this research, along with a motion planning algorithm. The quadcopter manipulator system comprises a robotic arm attached to the quadcopter’s center of gravity at its bottom. The manipulator has an extended workspace as its end-effector can reach three-dimensional locations above and below the drone’s airframe. The arm’s workspace is determined by system kinematics. Certain factors like downwash from the drone, the robotic arm’s singularity, servo motor stall torques, and mechanical structure limit the arm’s workspace during real-time tasks. A detailed description of these factors and their impact on the arm’s reachable workspace is also provided. Based on these limitations, the motion planning algorithm verifies the viability of a specific arm configuration and, therefore, the feasibility of the task. A concept called the near-wall effect and strategies to limit its influence on aerial robots are presented to comprehend the effect of a wall on the system in tasks involving targets on a compound wall. The proposed research outcomes are evaluated using MATLAB and ROS/Gazebo simulations.

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“…The value of the joint angle η 1 is derived using equations ( 22) and (23). Expanding the two equations and substituting d 2 sin η 2 = k 1 and…”

Section: Mathematical Preliminariesmentioning

confidence: 99%

“…The work in Ref. 23 presents a 3 DoF lightweight cable aerial manipulator installed on a platform with a counterbalance system for the CoG shift mechanism below the drone and its enhanced workspace. The review paper in Ref.…”

Section: Introductionmentioning

confidence: 99%

Effect of constraints and vertical wall interaction on workspace of a quadcopter manipulator system

Sumathy,

Warier,

Ghose

2023

Proceedings of the Institution of Mechanical Engineers, Part G:

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“…An essential consideration in the design of aerial manipulators and end-effectors is the achievement of lightweight structures with compact dimensions. Simultaneously, there is a focus on developing a straightforward and dependable control system with the aim of minimizing computational demands and reducing overall operational loads, as discussed in [17][18][19]. Finally, because conventional UAVs have a limited battery capacity, which determines maximum flight times and payloads, minimizing power consumption needs to be considered during the design phase.…”

Section: Introductionmentioning

confidence: 99%

A Fruit Harvesting Mechanism Capable of Multidimensional Movements: A Preliminary Study on the Integrated Mechanism with a Hexacopter

Park,

Kang,

Hwang

et al. 2024

Aerospace

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This study introduces a fruit harvesting mechanism powered by a single motor, designed for integration with unmanned aerial vehicles (UAVs). The mechanism performs reciprocating motion by converting linear motion into rotational motion. Consequently, the end-effector can execute multi-dimensional kinematic trajectories, including biaxial and rotational movements, synchronized with the motor’s position. These axial and rotational motions facilitate the gripper’s ability to reach, retrieve, and detach fruit from branches during the harvesting process. Notably, a critical consideration in designing this fruit harvesting mechanism is to generate the necessary torque at the end-effector while minimizing reaction forces and torque that could destabilize the UAV during flight. With these considerations in mind, this preliminary study aimed to harvest a Fuji apple and conduct a dynamic analysis. We constructed a prototype of the single motor-driven fruit harvesting mechanism using a suitable servo motor. To assess its mechanical performance and evaluate its impact on the hexacopter, we developed both a specific test platform featuring a six-spherical-prismatic-spherical parallel structure and a virtual environmental flight simulator. Overall, the results demonstrate the successful harvesting of a Fuji apple weighing approximately 300 g by the single motor-driven fruit harvesting mechanism, with no adverse effects observed on the hexacopter’s operation.

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“…In the following, a list of lightweight designs is presented in different scales such as refs. [23][24][25]. Bellocchio et al designed and developed a five-degree-of-freedom (DoF) aerial manipulator with 250 g weight and 200 g payload capacity [26].…”

Section: Introductionmentioning

confidence: 99%

A 94.1 g scissors-type dual-arm cooperative manipulator for plant sampling by an ornithopter using a vision detection system

et al. 2023

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The sampling and monitoring of nature have become an important subject due to the rapid loss of green areas. This work proposes a possible solution for a sampling method of the leaves using an ornithopter robot equipped with an onboard 94.1 g dual-arm cooperative manipulator. One hand of the robot is a scissors-type arm and the other one is a gripper to perform the collection, approximately similar to an operation by human fingers. In the move toward autonomy, a stereo camera has been added to the ornithopter to provide visual feedback for the stem, which reports the position of the cutting and grasping. The position of the stem is detected by a stereo vision processing system and the inverse kinematics of the dual-arm commands both gripper and scissors to the right position. Those trajectories are smooth and avoid any damage to the actuators. The real-time execution of the vision algorithm takes place in the lightweight main processor of the ornithopter which sends the estimated stem localization to a microcontroller board that controls the arms. The experimental results both indoors and outdoors confirmed the feasibility of this sampling method. The operation of the dual-arm manipulator is done after the perching of the system on a stem. The topic of perching has been presented in previous works and here we focus on the sampling procedure and vision/manipulator design. The flight experimentation also approves the weight of the dual-arm system for installation on the flapping-wing flying robot.

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The Design of a Lightweight Cable Aerial Manipulator with a CoG Compensation Mechanism for Construction Inspection Purposes

Cited by 15 publications

References 20 publications

Effect of constraints and vertical wall interaction on workspace of a quadcopter manipulator system

Effect of constraints and vertical wall interaction on workspace of a quadcopter manipulator system

A Fruit Harvesting Mechanism Capable of Multidimensional Movements: A Preliminary Study on the Integrated Mechanism with a Hexacopter

A 94.1 g scissors-type dual-arm cooperative manipulator for plant sampling by an ornithopter using a vision detection system

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