Selection and Mechanical Properties of High-Performance Fiber Ropes for the Jingping Neutrino Detector

LI Beibei; QI Wenqi; WANG Yuanqing; WANG Zongyi; CHEN Shaomin; ZHANG Tianxiong

doi:10.3724/j.gyjzG24112009

Volume 55 Issue 3

Mar. 2025

Turn off MathJax

Article Contents

Abstract

References

Article Navigation > INDUSTRIAL CONSTRUCTION > 2025 > 55(3): 27-33

LI Beibei, QI Wenqi, WANG Yuanqing, WANG Zongyi, CHEN Shaomin, ZHANG Tianxiong. Selection and Mechanical Properties of High-Performance Fiber Ropes for the Jingping Neutrino Detector[J]. INDUSTRIAL CONSTRUCTION, 2025, 55(3): 27-33. doi: 10.3724/j.gyjzG24112009

Citation:

LI Beibei, QI Wenqi, WANG Yuanqing, WANG Zongyi, CHEN Shaomin, ZHANG Tianxiong. Selection and Mechanical Properties of High-Performance Fiber Ropes for the Jingping Neutrino Detector[J]. INDUSTRIAL CONSTRUCTION, 2025, 55(3): 27-33. doi: 10.3724/j.gyjzG24112009

Citation:

LI Beibei, QI Wenqi, WANG Yuanqing, WANG Zongyi, CHEN Shaomin, ZHANG Tianxiong. Selection and Mechanical Properties of High-Performance Fiber Ropes for the Jingping Neutrino Detector[J]. INDUSTRIAL CONSTRUCTION, 2025, 55(3): 27-33. doi: 10.3724/j.gyjzG24112009

PDF( 1748 KB)

Selection and Mechanical Properties of High-Performance Fiber Ropes for the Jingping Neutrino Detector

doi: 10.3724/j.gyjzG24112009

1. College of Civil Engineering, Hefei University of Technology, Hefei 230009, China;
2. Key Laboratory of Civil Engineering Safety and Durability of China Education Ministry, Tsinghua University, Beijing 100084, China;
3. Department of Engineering Physics, Tsinghua University, Beijing, 100084, China

Received Date: 2024-11-20
Available Online: 2025-06-07
Publish Date: 2025-03-20

Abstract

Abstract

In the Jinping Neutrino Detector， the large-diameter acrylic vessel is filled with water or liquid scintillator as the target material both internally and externally. Due to the density difference between the internal and external liquids， low-background-content fiber ropes with high comprehensive performance are used to secure the sphere and prevent it from floating or sinking. For selecting a high-performance fiber rope suitable for the Jinping neutrino detector， the fracture test on 12-strand braided Technora， Vectran，JX99 and C90 fiber ropes with a diameter of 8 mm were respectively carried out. The results indicated that JX99 and C90 fiber ropes had comparable breaking force and tensile modulus， in which the breaking force of JX99 was 19.17% and 29.01% higher than that of Technora and Vectran fiber ropes， and the tensile modulus of JX99 was also 46.77% and 14.85% higher than that of Technora and Vectran fiber ropes. The preliminary creep test results showed that the Technora fiber rope exhibited superior resistance to rupture under high load levels compared to the other three types of fiber ropes， while its creep strain was comparable to that of the Vectran fiber rope. The JX99 fiber rope demonstrated significant creep strain values of up to 12% at 0.4 times the breaking force and 0.8% under design load conditions， indicating the poorest creep resistance. In contrast， the C90 fiber rope showed the minimal creep strain under design load levels.
- neutrino detector,
- high-performance fiber rope,
- fracture test,
- creep test

FullText(HTML)

References(22)

References

[1]	BEACOM J F，CHEN S M，CHENG J P，et al. Physics prospects of the Jinping neutrino experiment［J］. Chinese Physics C，2017，41（2），023002.
[2]	张天雄，王元清，陈志华，等. 合成纤维材料及其在中微子探测器中的应用［C］// 第十七届全国现代结构工程学术研讨会论文集. 天津：2017：1572- 1581.
[3]	林志娇，李兰英，何鑫业，等. 高伸级对位芳纶的性能、制备及应用概述［J］. 合成纤维，2020，49（2）：27- 31.
[4]	王新威，张玉梅，孙勇飞，等. 超高分子量聚乙烯材料的研究进展［J］. 化工进展，2020，39（9）：3403- 3420.
[5]	FINCKERNOR M M. Comparison of high-performance fiber materials properties in simulated and actual space environments［R］. Washington：NASA/TM-2017-219634，2017：1- 48.
[6]	李伟. Vectran纤维与绳索的蠕变与应力松弛行为研究［D］. 哈尔滨：哈尔滨工业大学，2010.
[7]	SHIGERU H． High-performance and specialty fibers［M］． Tokyo：Society of Fiber Science，2016：149- 169.
[8]	SMEETS P，JACOBS M，MERTENS M. Creep as a design tool for HMPE ropes in long term marine and offshore applications［C］// MTS/IEEE Conference and Exhibition OCEANS. 2001：685- 690.
[9]	WANG H Q，QUAN J Y，YU J R，et al. Enhanced wear resistance of ultra-high molecular weight polyethylene fibers by modified-graphite oxide［J］. Journal of Applied Polymer Science，2021，138（29），50696.
[10]	叶卓然，罗靓，潘海燕，等. 超高分子量聚乙烯纤维及其复合材料的研究现状与分析［J］. 复合材料学报，2022，39（9）：4286- 4309.
[11]	RAO Y Q，FARRIS R J. Fatigue and creep of high-performance fibers：deformation mechanics and failure criteria［J］. International Journal of Fatigue，2008，30：793- 799.
[12]	崔馨文，蒋金华，李俊. Vectran纤维在飞艇蒙皮材料中的力学性能研究［J］. 复合材料科学与工程，复合材料学报，2022（1）：73- 78.
[13]	马杰. 临近空间模拟环境下Kevlar和Vectran纤维织物损伤行为研究［D］. 天津：河北工业大学，2022.
[14]	SONG H R，YING P H，ZHU P P，et al. Modeling of load responses and aging of high strength fibers considering UV-radiation［J］. Composites Science and Technology，2023，231，109806.
[15]	丁许. 二维编织绳拉伸性能实验研究［D］. 天津：天津工业大学，2019.
[16]	魏雅斐. 聚芳酯纤维编织绳拉伸性能实验研究［D］. 天津：天津工业大学，2020.
[17]	董春晖，徐青华，孙颖，等. 聚芳酯纤维编织绳的拉伸性能［J］. 上海纺织科技，2022，50（3）：15- 18.
[18]	DEROMBISE G，SCHOORS L V V，DAVIES P. Degradation of Technora aramid fibres in alkaline and neutral environments［J］. Polymer Degradation and Stability，2009，94：1615- 1620.
[19]	DAVIES P，REAUD Y，DUSSUD L，et al. Mechanical behaviour of HMPE and aramid fibre ropes for deep sea handling operations［J］. Ocean Engineering，2011，38：2208- 2214.
[20]	刘克杰，杨琴，朱华兰，等．有机特种纤维介绍（一）［J］. 合成纤维，2013，42（1）：25- 29.
[21]	马福民，佘家全，梁劲松，等. 国内外对位芳纶产品结构及性能对比分析研究［J］. 塑料工业，2020，48（11）：94- 99.
[22]	中国国家标准化管理委员会. 纤维绳索有关物理和机械性能的测定：GB/T 8834—2016［S］. 北京：中国标准出版社，2016.