Milling diagnosis using artificial intelligence approaches

Knittel, Dominique; Makich, Hamid; Nouari, Mohammed

doi:10.1051/meca/2020053

Cited by 12 publications

(7 citation statements)

References 19 publications

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“…Water footprints, pollution level, and global warming impact measuring are other challenges Industry 4.0 tends to deal with in this sector, while Canizares and Valero [ 19 ] found that the improvements of using IoT technologies in metal machining are very high resulting in the higher efficiency and cost reduction. Maier et al [ 20 ] and Knittel et al [ 21 ] have noticed similar benefits from digitization of the tools.…”

Section: Introductionmentioning

confidence: 81%

Industry 4.0 Readiness Calculation—Transitional Strategy Definition by Decision Support Systems

Trstenjak

Opetuk

Cajner

et al. 2022

Sensors

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The digitization of the manufacturing industry, 10 years after the introduction of the Industry 4.0 concept, is still one of the most demanding tasks for the companies, especially for SMEs. As one of the biggest barriers in new business model implementation, the lack of strategy and workforce skills is frequently mentioned in the literature. The high level of investments it requires and the perception of high risks with unclear future benefits can be avoided with readiness factor calculation. This paper presents a novel model for readiness factor calculation, oriented to process planning and based on decision support systems. The model enables the definition of the optimal strategic plan for the digitization with the use of decision support systems (analytic hierarchy process) and through the use of statistical methods implemented within the model it minimizes the influence of human subjectivity and quantification of qualitative criteria. This innovative approach enables the understanding of the transition process to new technology-enabled business models, in this case oriented towards process planning. The useability and reliability of the model is proven in a case study of a metal machining company.

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Section: Introductionmentioning

confidence: 81%

Industry 4.0 Readiness Calculation—Transitional Strategy Definition by Decision Support Systems

Trstenjak

Opetuk

Cajner

et al. 2022

Sensors

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“…Glatt et al [80] predicted the martensite content after cryogenic turning, considering the passive, cutting and feed forces and temperature, applying the PCC approach for feature selection and obtaining a RMSE of~0.8. Linear kernel was also applied for flatness classification prediction in honeycomb cores using the time-domain and frequency-domain (based on FFT) features of the force signal and the PCA for feature reduction [81,82]. Finally, Nain et al [83] implemented a Gaussian Process with Polynomial Kernel to predict the SR peculiarities of WEDM.…”

Section: Qualitymentioning

confidence: 99%

Recent Advances on Machine Learning Applications in Machining Processes

2021

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This study aims to present an overall review of the recent research status regarding Machine Learning (ML) applications in machining processes. In the current industrial systems, processes require the capacity to adapt to manufacturing conditions continuously, guaranteeing high performance- in terms of production quality and equipment availability. Artificial Intelligence (AI) offers new opportunities to develop and integrate innovative solutions in conventional machine tools to reduce undesirable effects during operational activities. In particular, the significant increase of the computational capacity may permit the application of complex algorithms to big data volumes in a short time, expanding the potentialities of ML techniques. ML applications are present in several contexts of machining processes, from roughness quality prediction to tool condition monitoring. This review focuses on recent applications and implications, classifying the main problems that may be solved using ML related to the machining quality, energy consumption and conditional monitoring. Finally, a discussion on the advantages and limits of ML algorithms is summarized for future investigations.

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“…Also, several leading scientific journals are specifically dedicated to this research field involving many researchers and engineers from different disciplines: general computing, computer networks and IoT (Internet of Things), advanced statistics, signal processing, Artificial Intelligence, data science and data mining, intensive computing, embedded systems, etc.. Some diagnostic approaches are specifically designed or adapted for application fields and sectors such as manufacturing and production systems [3], industry 4.0 [4], material/tools interaction in milling [5] [6] [7], aeronautic sector [8], energy [9] [ 10], health [11], mobility/transport [12], waste management/wastewater treatment plants [13], rotating machines [14], … Predictive diagnostics and maintenance approaches are traditionally based on different methods:…”

Section: Introductionmentioning

confidence: 99%

Machine Learning based Real Time Predictive Maintenance at the Edge for Manufacturing Systems: A Practical Example

Ringler,

Knittel,

Ponsart

et al. 2023

2023 IEEE IAS Global Conference on Emerging Technologies (GlobConET)

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Edge Computing is becoming more and more essential for the Industrial Internet of Things (industrial IoT) for predictive maintenance in the industry 4.0 framework. The transition from central to distributed approaches (edge nodes), will enhance the capabilities of handling real-time big data from IoT by ensuring low latency and high bandwidth. Moreover, with the developed architecture the possibility is given to have distributed Machine Learning (ML) by enabling edge devices to learn local ML models. Therefore, the performances of the global diagnostic models can be improved. In this paper, the developed setup is composed of PC's, NVIDIA Jetson Nano Developers kits (for edge computing), and a smartphone for real-time displaying. The implemented real-time supervised machine learning approaches are applied on an industrial oilinjection screw compressor instrumented with vibration sensors. Time domain features are calculated online with the help of sliding windows and the features are automatically classified. Embedded in the equipment, the used algorithms obtained very good real-time diagnostic performances.

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Milling diagnosis using artificial intelligence approaches

Cited by 12 publications

References 19 publications

Industry 4.0 Readiness Calculation—Transitional Strategy Definition by Decision Support Systems

Industry 4.0 Readiness Calculation—Transitional Strategy Definition by Decision Support Systems

Recent Advances on Machine Learning Applications in Machining Processes

Machine Learning based Real Time Predictive Maintenance at the Edge for Manufacturing Systems: A Practical Example

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