Three-dimensional Deformed Multi-core Optical Fiber Reconstruction Technology for Skins of a Near-space AirshipLI Mohan

doi:10.3969/j.issn.1004-132X.2023.03.009

China Mechanical Engineering ›› 2023, Vol. 34 ›› Issue (03): 324-331.DOI: 10.3969/j.issn.1004-132X.2023.03.009

Previous Articles Next Articles

Three-dimensional Deformed Multi-core Optical Fiber Reconstruction Technology for Skins of a Near-space AirshipLI Mohan

MENG Kuo;SUN Guangkai;ZHOU Kangpeng;HE Yanlin;ZHU Lianqing

School of Instrument Science and Optoelectronic Engineering,Beijing Information Science and Technology University,Beijing,100192

Online:2023-02-10 Published:2023-02-27

临近空间飞艇蒙皮三维形变多芯光纤重构技术

李默涵;孟阔;孙广开;周康鹏;何彦霖;祝连庆

北京信息科技大学仪器科学与光电工程学院，北京，100192

通讯作者: 孟阔（通信作者），男，1982 年生，副研究员、博士。研究方向为光纤激光器和光纤传感等。E-mail:mengkuo@bistu.edu.cn。
作者简介:李默涵，女，1997 年生，硕士研究生。研究方向为光纤传感测量等。
基金资助:
国家自然科学基金(61903041，51705024)；北京市自然科学基金 (7202017，4204101)；北京市科技新星计划(Z191100001119052)；北京市教委科技计划重点项目(KZ201911232044)

Abstract

Abstract: In order to solve the problems of real-time monitoring of the airbag shapes of a near space airship, three-dimensional（3D） deformation reconstruction method of airbag skins was proposed based on temperature self-decoupling multi-core optical fiber sensor. According to the 3D shape characteristics of the airship airbags, the layout of the multi-core optical fiber sensors were designed. The sensing structure of multi-core optical fiber was combined with the Frenet-Serret equation to establish a 3D deformation reconstruction algorithm of the airship airbags with temperature self-decoupling function. Using flexible composite skins of the airship airbag as the test subjects, the 3D deformation multi-core optical fiber reconstruction test system of the airship airbag was designed and integrated. The test analyzed the 3D deformation reconstruction accuracy of the multi-core optical fiber sensors under the temperature change environments and the surface of airship airbag skins under different bending degrees, and verified the effectiveness of the method. The research results show that the method of multi-core optical fiber sensor with temperature self-decoupling may accurately reconstruct the deformation of the airship airbag skins in a large range of temperature environment, and the average value of the reconstruction errors of the 3D surface of the airship airbag skins is less than 1.5%. The real-time monitoring of shapes has application prospects.

Key words: near space airship, airbag shape monitoring, flexible composite skin, multi-core optical fiber sensor, 3D deformation reconstruction

摘要： 为解决临近空间飞艇气囊形态实时监测问题，提出了基于温度自解耦多芯光纤传感器的气囊蒙皮三维形变重构方法。根据飞艇气囊三维形态特征，设计了多芯光纤传感器布局和布设方式。将多芯光纤传感结构与Frenet-Serret方程相结合，建立了具备温度自解耦功能的蒙皮三维形变重构算法。以飞艇气囊柔性复合蒙皮为试验对象，设计并集成建立了蒙皮三维形变多芯光纤重构试验系统。试验分析了温度变化环境下多芯光纤传感器三维形变重构精度以及不同弯曲度下蒙皮三维形变型面重构精度，验证了所提方法的有效性。研究结果表明：利用多芯光纤传感器和温度自解耦方法能够在大变温环境下准确重构气囊蒙皮形变，蒙皮三维型面重构误差平均值小于1.5%，所提方法在临近空间飞艇气囊形态实时监测领域具有应用前景。

关键词: 临近空间飞艇, 气囊形态监测, 柔性复合蒙皮, 多芯光纤传感器, 三维形变重构

CLC Number:

V247

MENG Kuo, SUN Guangkai, ZHOU Kangpeng, HE Yanlin, ZHU Lianqing. Three-dimensional Deformed Multi-core Optical Fiber Reconstruction Technology for Skins of a Near-space AirshipLI Mohan[J]. China Mechanical Engineering, 2023, 34(03): 324-331.

李默涵, 孟阔, 孙广开, 周康鹏, 何彦霖, 祝连庆. 临近空间飞艇蒙皮三维形变多芯光纤重构技术[J]. 中国机械工程, 2023, 34(03): 324-331.

References

［1］MONDAL A, HOSSAIN A. An Optimal Model and Deployment Solution of Airship Based on Multiobjective Evolutionary Algorithm for Near Space Communication System［C］∥IEEE 7th Uttar Pradesh Section International Conference on Electrical, Electronics and Computer Engineering (UPCON). Prayagraj, India, 2020:1-6.
［2］DAI Q, CAO L, ZHANG G, et al. Thermal Performance Analysis of Solar Array for Solar Powered Stratospheric Airship［J］. Applied Thermal Engineering, 2020, 171:115077.
［3］ZHANG L, ZHU W, DU H, et al. Multidisciplinary Design of High Altitude Airship Based on Solar Energy Optimization［J］. Aerospace Science and Technology, 2021, 110:106440.
［4］邓小龙, 杨希祥, 麻震宇, 等. 基于风场环境利用的平流层浮空器区域驻留关键问题研究进展［J］. 航空学报, 2019, 40(8):23-36.
DENG Xiaolong, YANG Xixiang, MA Zhenyu, et al. Research Progress on Key Issues of Stratospheric Aerostat Regional Residence Based on Wind Farm Environment Utilization［J］. Acta Aeronautica et Astronautica Sinica, 2019, 40(8):23-36.
［5］彭海峰, 董二宝, 张世武, 等. 超弹性蒙皮蜂窝芯的设计及等效模量研究［J］. 中国机械工程, 2012, 23(6):717-720.
PENG Haifeng, DONG Erbao, ZHANG Shiwu, et al. Design and Equivalent Modulus of Superelastic Skin Honeycomb Core［J］. China Mechanical Engineering, 2012, 23(6):717-720.
［6］MAHMOOD K, ISMAIL N A, SUHADIS N M. Tethered Aerostat Envelope Design and Applications:a Review［J］.AIP Conference Proceedings, 2020, 2226(1):050003.
［7］MANIKANDAN M, PANT R S. Research and Advancements in Hybrid Airships—a Review［J］. Progress in Aerospace Sciences, 2021,127:100741.1-100741.25.
［8］KNAP L, Ｓ＇WIERCZ A, GRACZYKOWSKI C, et al. Self-deployable Tensegrity Structures for Adaptive Morphing of Helium-filled Aerostats［J］. Archives of Civil and Mechanical Engineering, 2021, 21(4):1-18.
［9］ANOOP S, VELAMATI R K, ORUGANTI V R M. Aerodynamic Characteristics of an Aerostat under Unsteady Wind Gust Conditions［J］. Aerospace Science and Technology, 2021, 113:106684.
［10］施红, 张彤, 高志刚, 等. 新型平流层飞艇定点热特性研究［J］. 机械工程学报, 2018,54(18):154-161.
SHI Hong, ZHANG Tong, GAO Zhigang, et al. Research on Fixed-point Thermal Characteristics of a New Type of Stratospheric Airship［J］. Journal of Mechanical Engineering, 2018,54(18):154-161.
［11］GHERLONE M, CERRACCHIO P, MATTONE M. Shape Sensing Methods:Review and Experimental Comparison on a Wing-shaped Plate［J］. Progress in Aerospace Sciences, 2018, 99:14-26.
［12］HU P, YANG S, ZHENG F, et al. Accurate and Dynamic 3D Shape Measurement with Digital Image Correlation-assisted Phase Shifting［J］. Measurement Science and Technology, 2021, 32(7):075204.
［13］张杰, 张吉旋, 马晓东. 基于数字散斑的大型机翼弹性形变测量技术［J］. 中国测试, 2021, 47(2):149-155.
ZHANG Jie, ZHANG Jixuan, MA Xiaodong. Large-scale Wing Elastic Deformation Measurement Technology Based on Digital Speckle［J］. China Test, 47(2):149-155.
［14］LU Lingling, SONG Hongwei, WANG Yiwei, et al. Deformation Behavior of Non-rigid Airships in Wind Tunnel Tests［J］. Chinese Journal of Aeronautics, 2019, 32(3):611-618.
［15］SCHAEFER P L, BARRIER G, CHAGNON G, et al. Strain Gauges Based 3d Shape Monitoring of Beam Structures Using Finite Width Gauge Model［J］. Experimental Techniques, 2019, 43(5):599-611.
［16］KHAN F, BARRERA D, SALES S, et al. Curvature, Twist and Pose Measurements Using Fiber Bragg Gratings in Multi-core Fiber:a Comparative Study between Helical and Straight Core Fibers［J］. Sensors and Actuators A:Physical, 2021, 317:112442.
［17］FLORIS I, ADAM J M, CALDERN P A, et al. Fiber Optic Shape Sensors:a Comprehensive Review［J］. Optics and Lasers in Engineering, 2021, 139:106508.
［18］LUN T L, WANG K, HO J D, et al. Real-time Surface Shape Sensing for Soft and Flexible Structures Using Fiber Bragg Gratings［J］. IEEE Robotics and Automation Letters, 2019, 4(2):1454-1461.
［19］赵士元, 崔继文, 陈勐勐. 光纤形状传感技术综述［J］. 光学精密工程, 2020, 28(1):10-29.
ZHAO Shiyuan, CUI Jiwen, CHEN Mengmeng. Overview of Optical Fiber Shape Sensing Technology［J］. Optics and Precision Engineering, 2020, 28(1):10-29.

Three-dimensional Deformed Multi-core Optical Fiber Reconstruction Technology for Skins of a Near-space AirshipLI Mohan

临近空间飞艇蒙皮三维形变多芯光纤重构技术

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 0

Recommended Articles

Metrics