Implementation of Robots Integration in Scaled Laboratory Environment for Factory Automation

Miskovic, Dragisa; Milić, Lazar; Čilag, Andrej; Berisavljević, Tanja; Gottscheber, Achim; Raković, Mirko

doi:10.3390/app12031228

Cited by 9 publications

(5 citation statements)

References 38 publications

(39 reference statements)

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“…Fitka et al developed a training tool for operating and programming KUKA industrial robots, offering practical and educational insights for integrating these robots into industrial setups [3]. Mišković et al proposed combining a cloud-based system, a prototyped mobile robot, and an ABB IRB 140 industrial robot, demonstrating potential advancements in factory automation [4]. Golz et al introduced the RoBO-2L Matlab Toolbox, enabling the extended offline programming of KUKA robots and integration with unsupported peripheral hardware and software [5].…”

Section: System Integration Toolboxesmentioning

confidence: 99%

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Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Rastegarpanah,

Mineo,

Contreras

et al. 2024

Batteries

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This paper showcases the integration of the Interfacing Toolbox for Robotic Arms (ITRA) with our newly developed hybrid Visual Servoing (VS) methods to automate the disassembly of electric vehicle batteries, thereby advancing sustainability and fostering a circular economy. ITRA enhances collaboration between industrial robotic arms, server computers, sensors, and actuators, meeting the intricate demands of robotic disassembly, including the essential real-time tracking of components and robotic arms. We demonstrate the effectiveness of our hybrid VS approach, combined with ITRA, in the context of Electric Vehicle (EV) battery disassembly across two robotic testbeds. The first employs a KUKA KR10 robot for precision tasks, while the second utilizes a KUKA KR500 for operations needing higher payload capacity. Conducted in T1 (Manual Reduced Velocity) mode, our experiments underscore a swift communication protocol that links low-level and high-level control systems, thus enabling rapid object detection and tracking. This allows for the efficient completion of disassembly tasks, such as removing the EV battery’s top case in 27 s and disassembling a stack of modules in 32 s. The demonstrated success of our framework highlights its extensive applicability in robotic manufacturing sectors that demand precision and adaptability, including medical robotics, extreme environments, aerospace, and construction.

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Section: System Integration Toolboxesmentioning

confidence: 99%

“…Several toolboxes have been developed to enhance system integration, incorporating sensors, actuators, and software [3][4][5][6]. However, many of these toolboxes are limited in capabilities or were designed for outdated generations of robot controllers, requiring advanced technical and programming skills.…”

Section: Introductionmentioning

confidence: 99%

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Rastegarpanah,

Mineo,

Contreras

et al. 2024

Batteries

View full text Add to dashboard Cite

show abstract

“…To assist humans, robots are being employed in different fields of industry and science [ 3 , 4 ], healthcare and medicine [ 5 , 6 , 7 ], hospitality and tourism [ 8 , 9 , 10 ], as domestic robots [ 11 ] and in many other areas. For such applications, humanoid robots are of special interest as they have similar body shapes as humans and could, therefore, learn to cooperate with them by mimicking human-like behavior.…”

Section: Introductionmentioning

confidence: 99%

Stable Heteroclinic Channel Networks for Physical Human–Humanoid Robot Collaboration

Brecelj

Petrič

2023

Sensors

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Human–robot collaboration is one of the most challenging fields in robotics, as robots must understand human intentions and suitably cooperate with them in the given circumstances. But although this is one of the most investigated research areas in robotics, it is still in its infancy. In this paper, human–robot collaboration is addressed by applying a phase state system, guided by stable heteroclinic channel networks, to a humanoid robot. The base mathematical model is first defined and illustrated on a simple three-state system. Further on, an eight-state system is applied to a humanoid robot to guide it and make it perform different movements according to the forces exerted on its grippers. The movements presented in this paper are squatting, standing up, and walking forwards and backward, while the motion velocity depends on the magnitude of the applied forces. The method presented in this paper proves to be a suitable way of controlling robots by means of physical human-robot interaction. As the phase state system and the robot movements can both be further extended to make the robot execute many other tasks, the proposed method seems to provide a promising way for further investigation and realization of physical human–robot interaction.

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“…However, there are drawbacks to such a wheel configuration: these wheels are mechanically complex and the wheels are sensitive to non-smooth surfaces and thus require either clean, flat floors or complex suspension systems that ensure that the wheels are in contact with the ground [ 6 ]. For this reason, while fully holonomic systems are common in academic research [ 7 ], very few commercial platforms exist, although an exception is the Omnibot from KUKA [ 8 ].…”

Section: Introductionmentioning

confidence: 99%

A Local Planner for Accurate Positioning for a Multiple Steer-and-Drive Unit Vehicle Using Non-Linear Optimization

Andreasson

Larsson

Lowry

2022

Sensors

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This paper presents a local planning approach that is targeted for pseudo-omnidirectional vehicles: that is, vehicles that can drive sideways and rotate on the spot. This local planner—MSDU–is based on optimal control and formulates a non-linear optimization problem formulation that exploits the omni-motion capabilities of the vehicle to drive the vehicle to the goal in a smooth and efficient manner while avoiding obstacles and singularities. MSDU is designed for a real platform for mobile manipulation where one key function is the capability to drive in narrow and confined areas. The real-world evaluations show that MSDU planned paths that were smoother and more accurate than a comparable local path planner Timed Elastic Band (TEB), with a mean (translational, angular) error for MSDU of (0.0028 m, 0.0010 rad) compared to (0.0033 m, 0.0038 rad) for TEB. MSDU also generated paths that were consistently shorter than TEB, with a mean (translational, angular) distance traveled of (0.6026 m, 1.6130 rad) for MSDU compared to (0.7346 m, 3.7598 rad) for TEB.

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Implementation of Robots Integration in Scaled Laboratory Environment for Factory Automation

Cited by 9 publications

References 38 publications

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Electric Vehicle Battery Disassembly Using Interfacing Toolbox for Robotic Arms

Stable Heteroclinic Channel Networks for Physical Human–Humanoid Robot Collaboration

A Local Planner for Accurate Positioning for a Multiple Steer-and-Drive Unit Vehicle Using Non-Linear Optimization

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