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Autores principales: Li, Jiajun, Heng, Yuekun, Huang, Tao, Ling, Jiajie, Tang, Xiao, Wu, Zhi, Yang, Chengfeng, Ye, Fan, Zhang, Shiqi, Zhang, Yinhong
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2507.09192
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author Li, Jiajun
Heng, Yuekun
Huang, Tao
Ling, Jiajie
Tang, Xiao
Wu, Zhi
Yang, Chengfeng
Ye, Fan
Zhang, Shiqi
Zhang, Yinhong
author_facet Li, Jiajun
Heng, Yuekun
Huang, Tao
Ling, Jiajie
Tang, Xiao
Wu, Zhi
Yang, Chengfeng
Ye, Fan
Zhang, Shiqi
Zhang, Yinhong
contents Jiangmen Underground Neutrino Observatory (JUNO) is a large-scale neutrino experiment with multiple physics goals including neutrino mass hierarchy, accurate measurement of neutrino oscillation parameters, neutrino detection from supernova, sun, and earth, etc. This paper presents the design, implementation, and verification of a high-reliability automated control system for the liquid Filling, Overflow, and Circulation system in the JUNO experiment. The system is built upon a Programmable Logic Controller architecture, integrated with high-precision sensors and actuators. It implements advanced control strategies, including Proportional-Integral-Derivative regulation, sequential logic, and safety interlocks, to achieve closed-loop control of critical parameters such as flow rate, liquid level, and pressure. Commissioning tests with both pure water and liquid scintillator demonstrate the system's exceptional performance, achieving flow control stability within 0.5% of the setpoint with a rapid stabilization time. The robust design, featuring hardware redundancy and software safeguards, ensures the system meets the stringent requirements for the safe filling and long-term stable operation of JUNO's 20-kiloton central detector and provides a scalable reference for large underground fluid control experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2507_09192
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Design and Verification of the JUNO Liquid Filling Control System
Li, Jiajun
Heng, Yuekun
Huang, Tao
Ling, Jiajie
Tang, Xiao
Wu, Zhi
Yang, Chengfeng
Ye, Fan
Zhang, Shiqi
Zhang, Yinhong
High Energy Physics - Experiment
Jiangmen Underground Neutrino Observatory (JUNO) is a large-scale neutrino experiment with multiple physics goals including neutrino mass hierarchy, accurate measurement of neutrino oscillation parameters, neutrino detection from supernova, sun, and earth, etc. This paper presents the design, implementation, and verification of a high-reliability automated control system for the liquid Filling, Overflow, and Circulation system in the JUNO experiment. The system is built upon a Programmable Logic Controller architecture, integrated with high-precision sensors and actuators. It implements advanced control strategies, including Proportional-Integral-Derivative regulation, sequential logic, and safety interlocks, to achieve closed-loop control of critical parameters such as flow rate, liquid level, and pressure. Commissioning tests with both pure water and liquid scintillator demonstrate the system's exceptional performance, achieving flow control stability within 0.5% of the setpoint with a rapid stabilization time. The robust design, featuring hardware redundancy and software safeguards, ensures the system meets the stringent requirements for the safe filling and long-term stable operation of JUNO's 20-kiloton central detector and provides a scalable reference for large underground fluid control experiments.
title Design and Verification of the JUNO Liquid Filling Control System
topic High Energy Physics - Experiment
url https://arxiv.org/abs/2507.09192