Study on the winding quality for spiral HTS cables based on AI detection model

Wang, Mingyang; Hao-sheng, YE; Wang, Xueliang; Li, Zhuyong; Sheng, Jie; Hong, Zhiyong; Jin, Zhijian

doi:10.1088/1361-6668/ac4952

Cited by 5 publications

(4 citation statements)

References 27 publications

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“…Winding methods also impact the quality of the cable and could increase the possibility of weak points and burnout during the operation of the cable. To avoid this, an AI-based technique with three steps was presented in [133] to analyse the quality of winding in a CORC cable. The first step was data preparation based on video of winding process and turning them into a couple of image samples.…”

Section: Ai For Superconducting Cablesmentioning

confidence: 99%

Artificial intelligence methods for applied superconductivity: material, design, manufacturing, testing, operation, and condition monitoring

Yazdani-Asrami

Sadeghi

Song

et al. 2022

Supercond. Sci. Technol.

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More than a century after the discovery of superconductors (SCs), numerous studies have been accomplished to take the advantage of SCs in physics, power engineering, quantum computing, electronics, communications, aviation, health care, and defence-related applications. However, there are still challenges that hinder the full-scale commercialization of SCs, such as the high cost of superconducting wires/tapes, technical issues related to AC losses, the structure of superconducting devices, the complexity and high cost of the cooling systems, the critical temperature, and manufacturing related issues. In the current century, massive advancements have been achieved on artificial intelligence (AI) techniques by offering disruptive solutions to handle engineering problems. Consequently, AI techniques can be implemented to tackle those challenges facing superconductivity and act as a shortcut towards full commercialization of SCs and their applications. AI approaches are capable of providing fast, efficient, and accurate solutions for the technical, manufacturing, and economic problems with a high level of complexity and nonlinearity in the field of superconductivity. In this paper, concept of AI and the widely used algorithms are first given. Then a critical topical review is presented for those conducted studies that used AI methods for improvement, design, condition monitoring, fault detection and location of superconducting apparatuses in large scale power applications, as well as the prediction of critical temperature and the structure of new SCs, and any other related applications. The topical review are presented in three main categories, AI for large-scale superconducting applications, AI for superconducting materials, and AI for physics of superconductors. In addition, the challenges to apply AI techniques to the superconductivity and its applications are given. Eventually, future trends on how to integrate AI techniques with superconductivity towards the commercialization are discussed.

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Section: Ai For Superconducting Cablesmentioning

confidence: 99%

Artificial intelligence methods for applied superconductivity: material, design, manufacturing, testing, operation, and condition monitoring

Yazdani-Asrami

Sadeghi

Song

et al. 2022

Supercond. Sci. Technol.

View full text Add to dashboard Cite

show abstract

“…The development of new high-quality HTS tapes has opened up opportunities for device manufacturers to explore novel structural designs for HTS cables, including the spiral geometry, which has gained popularity as a compact HTS cable structure. However, one of the main challenges in manufacturing spiral HTS cables lies in the instability of the winding quality due to various winding methods, such as manual winding, device-assisted winding, or automatic winding [19]. In [19], an AI-based model is developed to monitor the winding quality and prevent errors during automatic winding.…”

Section: Condition Monitoringmentioning

confidence: 99%

“…However, one of the main challenges in manufacturing spiral HTS cables lies in the instability of the winding quality due to various winding methods, such as manual winding, device-assisted winding, or automatic winding [19]. In [19], an AI-based model is developed to monitor the winding quality and prevent errors during automatic winding. The model encompasses image data preparation, AI detection, and post-processing, ultimately providing the final results in the form of a binary image that shows the winding intervals.…”

Section: Condition Monitoringmentioning

confidence: 99%

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Artificial intelligence, machine learning, deep learning, and big data techniques for the advancements of superconducting technology: a road to smarter and intelligent superconductivity

Yazdani-Asrami

2023

Supercond. Sci. Technol.

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The last 100 years of experience within the superconducting community have proven that addressing the challenges faced by this technology often requires incorporation of other disruptive techniques or technologies into superconductivity. Artificial intelligence (AI) methods including machine learning, deep learning, and big data techniques have emerged as highly effective tools in resolving challenges across various industries in recent decades. The concept of AI entails the development of computers that resemble human intelligence. The papers published in this focus issue represent the cutting-edge and forefront research activities in the field of artificial intelligence for superconductivity.

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Estimation of critical current density of bulk superconductor with artificial neural network

Yong

2023

Superconductivity

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Study on the winding quality for spiral HTS cables based on AI detection model

Cited by 5 publications

References 27 publications

Artificial intelligence methods for applied superconductivity: material, design, manufacturing, testing, operation, and condition monitoring

Artificial intelligence methods for applied superconductivity: material, design, manufacturing, testing, operation, and condition monitoring

Artificial intelligence, machine learning, deep learning, and big data techniques for the advancements of superconducting technology: a road to smarter and intelligent superconductivity

Estimation of critical current density of bulk superconductor with artificial neural network

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