Reliable Identification Schemes for Asset and Production Tracking in Industry 4.0

Frankó, Attila; Vida, Gergely; Varga, Pál

doi:10.3390/s20133709

Cited by 59 publications

(27 citation statements)

References 54 publications

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“…A new technological era, called Industry 4.0, will change all manufacturing-related fields [ 1 ]. The industrial and production processes will be transformed into intelligent factory systems [ 2 ].…”

Section: Introductionmentioning

confidence: 99%

Automatic Identification of Tool Wear Based on Thermography and a Convolutional Neural Network during the Turning Process

Brili

Ficko

Klančnik

2021

Sensors

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This article presents a control system for a cutting tool condition supervision, which recognises tool wear automatically during turning. We used an infrared camera for process control, which—unlike common cameras—captures the thermographic state, in addition to the visual state of the process. Despite challenging environmental conditions (e.g., hot chips) we protected the camera and placed it right up to the cutting knife, so that machining could be observed closely. During the experiment constant cutting conditions were set for the dry machining of workpiece (low alloy carbon steel 1.7225 or 42CrMo4). To build a dataset of over 9,000 images, we machined on a lathe with tool inserts of different wear levels. Using a convolutional neural network (CNN), we developed a model for tool wear and tool damage prediction. It determines the state of a cutting tool automatically (none, low, medium, high wear level), based on thermographic process data. The accuracy of classification was 99.55%, which affirms the adequacy of the proposed method. Such a system enables immediate action in the case of cutting tool wear or breakage, regardless of the operator’s knowledge and competence.

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Section: Introductionmentioning

confidence: 99%

Automatic Identification of Tool Wear Based on Thermography and a Convolutional Neural Network during the Turning Process

Brili

Ficko

Klančnik

2021

Sensors

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“…Corotinschi and Gȃitan [2] show that the evolution of industrial production has occurred in four stages culminating in the IoT: (1) mechanization and the invention of the steam engine and water power, (2) mass production and assembly lines, (3) the computer and automation processing, (4) the Internet of Things (IoT), (5) the collaboration between man and machine in industry and robotic tasks conversion. These stages are referred to as Industry 1.0, Industry 2.0, Industry 3.0, Industry 4.0, and Industry 5.0.…”

Section: Introductionmentioning

confidence: 99%

“…In addition to management, advanced computation, and intelligent decision making, IoT will provide us with control over the entirety of any process, such as the life cycle of products. Frankó et al [4] depicts an example of industry 4.0 in supply chain management and asset monitoring. Massaro and Galiano [5] demonstrates another example of industry 4.0 in the optimization of pasta line production.…”

Section: Introductionmentioning

confidence: 99%

Process Automation in an IoT–Fog–Cloud Ecosystem: A Survey and Taxonomy

Chegini

Naha

Mahanti

et al. 2021

IoT

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The number of IoT sensors and physical objects accommodated on the Internet is increasing day by day, and traditional Cloud Computing would not be able to host IoT data because of its high latency. Being challenged of processing all IoT big data on Cloud facilities, there is not enough study on automating components to deal with the big data and real-time tasks in the IoT–Fog–Cloud ecosystem. For instance, designing automatic data transfer from the fog layer to cloud layer, which contains enormous distributed devices is challenging. Considering fog as the supporting processing layer, dealing with decentralized devices in the IoT and fog layer leads us to think of other automatic mechanisms to manage the existing heterogeneity. The big data and heterogeneity challenges also motivated us to design other automatic components for Fog resiliency, which we address as the third challenge in the ecosystem. Fog resiliency makes the processing of IoT tasks independent to the Cloud layer. This survey aims to review, study, and analyze the automatic functions as a taxonomy to help researchers, who are implementing methods and algorithms for different IoT applications. We demonstrated the automatic functions through our research in accordance to each challenge. The study also discusses and suggests automating the tasks, methods, and processes of the ecosystem that still process the data manually.

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“…The qualitative leap that accompanies the fourth industrial revolution results in humans and machines co-creating a production system [ 15 ]. In this system, various components can be distinguished: Incremental manufacturing (3D printing)—used to produce complete products [ 16 , 17 , 18 ], systems integration—the flow of data and control signals between machines, information systems, people and management systems [ 19 , 20 , 21 , 22 ], Industrial Internet of Things (IIoT)—the unified integration of statuary and management systems [ 23 , 24 ], Cloud computing—making external hardware and software resources available to process production data and perform complex calculations for the production process itself as well as for management systems [ 25 , 26 , 27 ], big data analysis (Big Data)—i.e., the use of large computing powers to collect, store and analyze large amounts of data [ 28 , 29 ], augmented and virtual reality (AR and VR) [ 30 , 31 , 32 ]—technologies that are proposing to move industry to virtual and augmented reality, Cyber security—which plays a huge role in cloud computing and analyzing large data sets on external servers [ 33 , 34 ]. …”

Section: Introductionmentioning

confidence: 99%

“…systems integration—the flow of data and control signals between machines, information systems, people and management systems [ 19 , 20 , 21 , 22 ],…”

Section: Introductionmentioning

confidence: 99%

Controlling an Industrial Robot Using a Graphic Tablet in Offline and Online Mode

Kaczmarek

Lotys²,

Borys

et al. 2021

Sensors

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The article presents the possibility of using a graphics tablet to control an industrial robot. The paper presents elements of software development for offline and online control of a robot. The program for the graphic tablet and the operator interface was developed in C# language in Visual Studio environment, while the program controlling the industrial robot was developed in RAPID language in the RobotStudio environment. Thanks to the development of a digital twin of the real robotic workstation, tests were carried out on the correct functioning of the application in offline mode (without using the real robot). The obtained results were verified in online mode (on a real production station). The developed computer programmes have a modular structure, which makes it possible to easily adapt them to one’s needs. The application allows for changing the parameters of the robot and the parameters of the path drawing. Tests were carried out on the influence of the sampling frequency and the tool diameter on the quality of the reconstructed trajectory of the industrial robot. The results confirmed the correctness of the application. Thanks to the new method of robot programming, it is possible to quickly modify the path by the operator, without the knowledge of robot programming languages. Further research will focus on analyzing the influence of screen resolution and layout scale on the accuracy of trajectory generation.

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Reliable Identification Schemes for Asset and Production Tracking in Industry 4.0

Cited by 59 publications

References 54 publications

Automatic Identification of Tool Wear Based on Thermography and a Convolutional Neural Network during the Turning Process

Automatic Identification of Tool Wear Based on Thermography and a Convolutional Neural Network during the Turning Process

Process Automation in an IoT–Fog–Cloud Ecosystem: A Survey and Taxonomy

Controlling an Industrial Robot Using a Graphic Tablet in Offline and Online Mode

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