Industry 4.0 Application in Manufacturing for Real-Time Monitoring and Control

Mishra, Debasish; Priyadarshi, Ashok; Das, Sarthak M.; Shree, Sristi; Gupta, Akhilesh; Pal, Surjya K.; Chakravarty, Debashish

doi:10.37965/jdmd.2022.118

Cited by 5 publications

(4 citation statements)

References 28 publications

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“…The emergence of deep learning has revolutionized the landscape of polymer processing detection, enabling researchers to harness the capabilities of NNs and advanced deep learning techniques. By leveraging the power of NNs and other deep learning techniques, researchers across different fields can more effectively analyze large datasets and extract meaningful insights from complex systems 18–23 . As a result, deep learning is becoming an increasingly popular tool for optimizing processing procedures and improving the quality and efficiency of polymer products.…”

Section: Introductionmentioning

confidence: 99%

“…By leveraging the power of NNs and other deep learning techniques, researchers across different fields can more effectively analyze large datasets and extract meaningful insights from complex systems. [18][19][20][21][22][23] As a result, deep learning is becoming an increasingly popular tool for optimizing processing procedures and improving the quality and efficiency of polymer products.…”

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confidence: 99%

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Multi‐source data‐driven approach for prediction of melt density during polymer compounding

Zhang,

Chen,

Zhang

et al. 2024

Polymer Engineering & Sci

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Melt density is a crucial quality indicator for polymer composites, yet real‐time measurement remains challenging due to processing complexities. While existing machine learning methods offer solutions, they often fall short in complex compounding scenarios. This study presents a novel multi‐source data‐driven approach for measuring melt density in polycarbonate/acrylonitrile butadiene styrene blends. By incorporating ultrasonic, near‐infrared, and Raman spectra data acquired during melt processing, a deep separable convolutional neural network model is developed to predict melt density accurately. The model effectively fuses multi‐source data to establish the mapping relationship between input data and melt density output. Results demonstrate the model's ability to monitor melt density in real‐time, achieving a prediction accuracy with RMSE and R2 indexes of 0.005 g/cm3 and 0.9841, respectively. The proposed approach outperforms existing methods, showcasing its effectiveness and superiority in melt density prediction for polymer compounding processes.Highlights Establishment of the real‐time monitoring system for polymer extrusion processes. Conversion of multi‐sensor signals into time‐frequency images using wavelet decomposition. Fusion of sensor data into a three‐channel tensor‐image. Development of a data‐driven DSCNN model for predicting melt density. Implementation for online monitoring and prediction in PC/ABS compounding system.

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Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Multi‐source data‐driven approach for prediction of melt density during polymer compounding

Zhang,

Chen,

Zhang

et al. 2024

Polymer Engineering & Sci

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“…Recently, deep learning models have emerged as a powerful approach that eliminates the need for extensive feature engineering by automatically learning hierarchical representations from raw data [ 25 ]. The method presents advantages in comparison with signal processing methods and traditional machine learning techniques in different areas [ 26 , 27 , 28 ]. Deep neural networks, a popular type of deep learning model, have demonstrated impressive performance in addressing complex tasks like image recognition, natural language processing, and condition monitoring of assets [ 29 , 30 , 31 ].…”

Section: Introductionmentioning

confidence: 99%

Long-Short-Term-Memory-Based Deep Stacked Sequence-to-Sequence Autoencoder for Health Prediction of Industrial Workers in Closed Environments Based on Wearable Devices

Xu,

He,

et al. 2023

Sensors

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To reduce the risks and challenges faced by frontline workers in confined workspaces, accurate real-time health monitoring of their vital signs is essential for improving safety and productivity and preventing accidents. Machine-learning-based data-driven methods have shown promise in extracting valuable information from complex monitoring data. However, practical industrial settings still struggle with the data collection difficulties and low prediction accuracy of machine learning models due to the complex work environment. To tackle these challenges, a novel approach called a long short-term memory (LSTM)-based deep stacked sequence-to-sequence autoencoder is proposed for predicting the health status of workers in confined spaces. The first step involves implementing a wireless data acquisition system using edge-cloud platforms. Smart wearable devices are used to collect data from multiple sources, like temperature, heart rate, and pressure. These comprehensive data provide insights into the workers’ health status within the closed space of a manufacturing factory. Next, a hybrid model combining deep learning and support vector machine (SVM) is constructed for anomaly detection. The LSTM-based deep stacked sequence-to-sequence autoencoder is specifically designed to learn deep discriminative features from the time-series data by reconstructing the input data and thus generating fused deep features. These features are then fed into a one-class SVM, enabling accurate recognition of workers’ health status. The effectiveness and superiority of the proposed approach are demonstrated through comparisons with other existing approaches.

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“…In recent years, with the development of the industrial 4.0 system, bigdata analysis techniques based on real-time condition monitoring have been widely applied [12,13]. The main goal is to continuously monitor and assess high-value equipment in real-time.…”

Section: Introductionmentioning

confidence: 99%

Online Big-Data Monitoring and Assessment Framework for Internal Combustion Engine with Various Biofuels

Zhang

Sharma

Wang

et al. 2023

IJAMM

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Article Online Big-Data Monitoring and Assessment Framework for Internal Combustion Engine with Various Biofuels Ming Zhang 1,*, Vikas Sharma 2, Zezhong Wang 1, Yu Jia 1, Abul Kalam Hossain 1, and Yuchun Xu 1 1 College of Engineering and Physical Sciences, Aston University, Birmingham B4 7ET, UK 2 School of Architecture, Technology and Engineering, University of Brighton, Brighton BN2 4GJ, UK * Correspondence: m.zhang21@aston.ac.uk Received: 14 December 2022 Accepted: 26 April 2023 Published: 30 May 2023 Abstract: As the primary power source for automobiles, the internal combustion (IC) engines have been widely used and served millions of people worldwide. With increasingly stringent environmental regulations, biofuels have been obtained more attentions and are being used as alternative fuel to power IC engines. However, there are currently no standard solutions or well-established monitoring and assessment methods that can effectively evaluate the IC engine’s performance with biofuels. The expectation for biofuels is to keep the engine’s lifetime as long as the conventional fuels, or even longer. Otherwise, their usage would be unnecessary because they would reduce the lifecycle of the engine and also cause more waste and pollution. To address this challenge, we initially designed two biofuels: waste cooking oil biofuel (WCOB) and lamb fat biofuel (LFB). Then we proposed an online big-data monitoring and assessment framework for IC engines operating with various types of fuel. We conducted comprehensive experiments and comparisons based on the proposed framework. The results indicate that LFB performs best under all the performance indicators.

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Industry 4.0 Application in Manufacturing for Real-Time Monitoring and Control

Cited by 5 publications

References 28 publications

Multi‐source data‐driven approach for prediction of melt density during polymer compounding

Multi‐source data‐driven approach for prediction of melt density during polymer compounding

Long-Short-Term-Memory-Based Deep Stacked Sequence-to-Sequence Autoencoder for Health Prediction of Industrial Workers in Closed Environments Based on Wearable Devices

Online Big-Data Monitoring and Assessment Framework for Internal Combustion Engine with Various Biofuels

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