Flexible skill-based control for robot cells in manufacturing

Wiese, Torben; Abicht, Johannes; Friedrich, Christian; Hellmich, Arvid; Ihlenfeldt, Steffen

doi:10.3389/frobt.2022.1014476

Cited by 7 publications

(8 citation statements)

References 22 publications

(29 reference statements)

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“…The use of eccentric joints ensures both high accuracy and stiffness, while keeping the cost at an affordable level [33]. The Beckhoff TwinCAT control facilitates numerical controlled G-code processing and offers a user-friendly web-based human machine interface (HMI) for controlling the machine and extruder featuring skill-based control [34]. A high level of precision is ensured through a kinematic calibration using the double-ball-bar measuring instrument [31,35].…”

Section: Methodsmentioning

confidence: 99%

Additive In-Time Manufacturing of Customised Orthoses

Friedrich,

Rothstock,

Slabon

et al. 2024

JMMP

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Additive manufacturing of plastic components in medical technology enables greater freedom of design when designing patient-specific products, in particular, in production of customised medical products, such as orthoses. In the present contribution, the advantages of a digital process chain are combined, from the 3D scan of the patient to CAD-supported modelling of the corrective form and the orthosis design until the path planning of a printable geometry. The main disadvantages of current additive printing techniques, such as the fused filament fabrication (FFF) process, are high printing times (>12 h) for larger components as well as the low degree of freedom in the 2.5D printing technique that prevent the subsequent application of geometry features to the product. The fast SEAMHex (Screw Extrusion Additive Manufacturing) printing technology with a hexapod kinematic printing bed provides a solution to the mentioned difficulties. Consequently, the high-performance printer has been prepared for the individual requirements of medical technology in terms of materials and geometries. An effective additive manufacturing process has been realised and tested in combination with a digital process chain for orthosis modelling.

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Section: Methodsmentioning

confidence: 99%

Additive In-Time Manufacturing of Customised Orthoses

Friedrich,

Rothstock,

Slabon

et al. 2024

JMMP

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“…Although this is a different domain of robotics, the concept of industrial cobots is very similar to that of medical robots because it is based on direct human-robot collaboration. Wiese et al, who developed a flexible control for robot cells in manufacturing, state that skill-based control architecture lets us fulfill four basic requirements regarding effective robot control: extensibility, flexible usability, configurability, and reusability [ 44 ]. Another example of a skill-based approach is the work of Pane et al, who developed a programming framework that allows several skills to run synchronously in the presence of disturbances [ 45 ].…”

Section: Methodsmentioning

confidence: 99%

Scenario-Based Programming of Voice-Controlled Medical Robotic Systems

Rogowski

2022

Sensors

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An important issue in medical robotics is communication between physicians and robots. Speech-based communication is of particular advantage in robot-assisted surgery. It frees the surgeon’s hands; hence, he can focus on the principal tasks. Man-machine voice communication is the subject of research in various domains (industry, social robotics), but medical robots are very specific. They must precisely synchronize their activities with operators. Voice commands must be possibly short. They must be executed without significant delays. An important factor is the use of a vision system that provides visual information in direct synchronization with surgeon actions. Its functions could be also controlled using speech. The aim of the research presented in this paper was to develop a method facilitating creation of voice-controlled medical robotic systems, fulfilling the mentioned requirements and taking into account possible scenarios of man-machine collaboration in such systems. A robot skill description (RSD) format was proposed in order to facilitate programming of voice control applications. A sample application was developed, and experiments were conducted in order to draw conclusions regarding the usefulness of speech-based interfaces in medical robotics. The results show that a reasonable selection of system functions controlled by voice may lead to significant improvement of man-machine collaboration.

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“…An autonomous error handling system enables a situation-appropriate ability to act in the event of malfunctions. By means of a skill-based control, the operator tasks are programmed in skills [14]. Fig.…”

Section: Use Cases For Autonomous Applications In Manufacturingmentioning

confidence: 99%

“…7. Robo Operator [14] Figure 8 shows a method for autonomous straightening processes, which is currently being developed by Fraunhofer IWU in Chemnitz. This intelligent robotic roll forming (iRoRoFo) is being developed to automate straightening processes.…”

Section: Use Cases For Autonomous Applications In Manufacturingmentioning

confidence: 99%

Autonomous Assembly and Disassembly - Key Technologies and Links for the Adaptive Self-Optimization of Future Circular Production

Ihlenfeldt¹,

Lorenz²,

Frieß³

et al. 2023

Journal of Machine Engineering

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European industry and beyond, faces the challenge of becoming carbon neutral within an unprecedented short timeframe. An important approach to achieve this goal is the transformation of the current economy to a circular economy. In this context, the reuse of technical products as well as their recycling are in the foreground. Flexibility and adaptability are crucial for the competitiveness of companies. Therefore, adaptive and autonomous assembly and disassembly systems are the key. Classically automated assembly systems are inflexible due to a mostly rigid and predefined sequence control and are mostly strongly oriented towards economic criteria. Existing autonomous production cells, with their focus on autonomy and failure-free operation, also reach their limits in terms of adaptivity. For this reason, intelligent systems are needed that are able to act autonomously and without interference, as well as to cope with complex and cognitively demanding situations and tasks.

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Flexible skill-based control for robot cells in manufacturing

Cited by 7 publications

References 22 publications

Additive In-Time Manufacturing of Customised Orthoses

Additive In-Time Manufacturing of Customised Orthoses

Scenario-Based Programming of Voice-Controlled Medical Robotic Systems

Autonomous Assembly and Disassembly - Key Technologies and Links for the Adaptive Self-Optimization of Future Circular Production

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