纤维缠绕复合材料压力容器的研究现状

doi:10.3969/j.issn.1001-4837.2021.04.008

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压力容器 ›› 2021, Vol. 38 ›› Issue (4) : 53-63. DOI: 10.3969/j.issn.1001-4837.2021.04.008

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技术综述

纤维缠绕复合材料压力容器的研究现状

惠虎¹, 柏慧¹, 黄淞¹, 杨宇清²

作者信息 +

Research on fiber composites overwrapped pressure vessels

HUI Hu¹, BAI Hui¹, HUANG Song¹, YANG Yuqing²

Author information +

文章历史 +

摘要

介绍了纤维增强树脂基复合材料以及纤维缠绕压力容器的分类和应用，归纳了纤维缠绕压力容器在国内外常用的相关标准，并针对其设计优化和健康监测与检测两个方面，总结了国内外的研究进展。

Abstract

The classification and application of fiber reinforced resin matrix composites and fiber composites overwrapped pressure vessels are introduced.Relevant common standards of fiber wound pressure vessels at home and aboard are summarized.In addition,the domestic and foreign research progresses are summarized in terms of design optimization and health monitoring or detection.

导出引用

惠虎, 柏慧, 黄淞, 杨宇清. 纤维缠绕复合材料压力容器的研究现状[J]. 压力容器, 2021, 38(4): 53-63 https://doi.org/10.3969/j.issn.1001-4837.2021.04.008

HUI Hu, BAI Hui, HUANG Song, YANG Yuqing. Research on fiber composites overwrapped pressure vessels[J]. Pressure Vessel Technology, 2021, 38(4): 53-63 https://doi.org/10.3969/j.issn.1001-4837.2021.04.008

参考文献

[1] HAN M G,CHANG S H.Failure analysis of a type Ⅲ hydrogen pressure vessel under impact loading induced by free fall[J].Composite Structures,2015,127:288-297.
[2] 邬丹丹.碳纤维缠绕复合材料气瓶的有限元数值分析[D].大连:大连理工大学,2007.WU D D.Numerical analysis of the carbon-fibre winding pressure vessel using finite element method[D].Dalian:Dalian University of Technology,2007.
[3] 杨帆.金属内衬纤维缠绕复合材料压力容器强度分析[D].杭州:浙江大学,2010.YANG F.Strength analysis of filament wound composite pressure vessel with a metal liner[D].Hangzhou:Zhejiang University,2010.
[4] 王婉君,张鹏,贺政豪,等.碳纤维复合材料压力容器的研究进展[J].现代化工,2020,40(1):68-71. WANG W J,ZHANG P,HE Z H,et al.Research progress on carbon fiber composites-based pressure vessel[J].Modern Chemical Industry,2020,40(1):68-71.
[5] BAI H,YANG B,HUI H,et al.Experimental and numerical investigation of the strain response of the filament wound pressure vessels subjected to pressurization test[J].Polymer Composites,2019,40(11):4427-4441.
[6] MARTINS A T,ABOURA Z,HARIZI W,et al.Structural health monitoring for GFRP composite bythe piezoresistive response in the tufted reinforcements[J].Composite Structures,2019,209:103-111.
[7] 阮润女,程浩南.玻璃纤维及其制品的应用与发展[J].产业用纺织品,2018,36(7):38-41. RUAN R N,CHENG H N.Application and development of glass fiber and its products[J].Technical Textiles,2018,36(7):38-41.
[8] 朱伸兵.玻璃纤维/PDCPD增强复合材料制备及性能研究[D].洛阳:河南科技大学,2013. ZHU S B.Study on preparation and properties of fiber reinforced polidicyclopentadiene[D].Luoyang:Henan University of Science and Technology,2013.
[9] KASAAI M R,ARUL J,CHARLET G.Intrinsic viscosity-Molecular weight relationship for chitosan[J].Journal of Polymer Science Part B:Polymer Physics,2015,38(19):2591-2598.
[10] 李豫卿.浅谈碳纤维复合材料在航空工业的发展与展望[J].合成材料老化与应用,2015,44(3):134-136. LI Y Q.Discussion on development and prospect of carbon fiber composite materials in aviation industry[J].Synthetic Materials Aging and Application,2015,44(3):134-136.
[11] 贾立军,朱虹.复合材料加工工艺[M].天津:天津大学出版社,2007. JIA L J,ZHU H.Processing technology of composites[M].Tianjin:Tianjin University Press,2007.
[12] 王亮.基于微观力学分析的复合材料储氢容器强度与寿命研究[D].杭州:浙江大学,2016. WANG L.Micromechanics-based failure theory for strength and life investigation of carbon fiber-reinforced composite hydrogen storage vessel[D].Hangzhou:Zhejiang University,2016.
[13] 张晓虎,孟宇,张炜.碳纤维增强复合材料技术发展现状及趋势[J].纤维复合材料,2004,21(1):50-53. ZHANG X H,MENG Y,ZHANG W.The state of the art and trend of carbon fiber reinforced composites[J].Fiber Composites,2004,21(1):50-53.
[14] 王恺,吴茜,汪文博,等.可重复使用复合材料气瓶的设计及试验验证[J].宇航材料工艺,2018,48(6):16-20. WANG K,WU Q,WANG W B,et al.Design andexperimental verification of reusable composite pressure vessel[J].Aerospace Materials and Technology,2018,48(6):16-20.
[15] 缐永兴.碳纤维全缠绕复合气瓶缠绕方式的设计与选择[D].北京:北京工业大学,2015. XIAN Y X.Winding pattern design and selection of full wrapped composite cylinders[D].Beijing:Beijing University of Technology,2015.
[16] NOBUHIKO T,HIROSHI S,TOMOYUKI Y,et al."Hybrid hydrogen storage vessel",a novel high-pressure hydrogen storage vessel combined with hydrogen storage material[J].International Journal of Hydrogen Energy,2003,28(10):1121-1129.
[17] 陈建良,童水光.复合材料在压力容器中的应用[J].压力容器,2001,18(6):47-50. CHEN J L,TONG S G.The application of composite materials to pressure vessels[J].Pressure Vessel Technology,2001,18(6):47-50.
[18] GRIMSLEY B W,CANO R J,JOHNSTON N J,et al.Hybrid composites for LH2 fuel tank structure[C]//33rd International SAMPE Technical Conference,2001:1224-1235.
[19] 费川,董鹏.复合材料气瓶的特点及其应用[J].纤维复合材料,2014,31(2):53-55. FEI C,DONG P.Characteristic and application of composite gas cylinder[J].Fiber Composites,2014,31(2):53-55.
[20] 王冬旭.复合材料气瓶冲击后损伤与剩余爆破压力研究[D].哈尔滨:哈尔滨工业大学,2013. WANG D X.Study on the damage and residual burst-pressure of COPV after impact[D].Harbin:Harbin Institute of Technology,2013.
[21] 欧可升.碳纤维全缠绕复合材料高压储氢气瓶耐局部火烧性能研究[D].杭州:浙江大学,2014. OU K S.Research on fully-wrapped carbon fiber reinforced composite high-pressure hydrogen storage cylinder[D].Hangzhou:Zhejiang University,2014.
[22] 郑津洋,傅强,开方明,等.轻质高压贮氢容器的现状及发展趋势[J].太阳能学报,2004,25(5):576-581. ZHENG J Y,FU Q,KAI F M,et al.The state of art of lightweight high-pressure hydrogen storage tanks[J].Acta Energiae Solaris Sinica,2004,25(5):576-581.
[23] 张宁,霍新立,常新刚,等.耐腐蚀玻璃钢大型贮罐在油田的应用[J].内蒙古石油化工,2012,38(8):11-12.ZHANG N,HUO X L,CHANG X G,et al.Application of corrosion resistant FRP large storage tank in oil field[J].Inner Mongolia Petrochemical Industry,2012,38(8):11-12.
[24] 周海成,阮海东.纤维缠绕复合材料气瓶的发展及其标准情况[J].压力容器,2004,21(9):32-36. ZHOU H C,RUAN H D.Development of filament wound composite gas cylinder and its standard condition[J].Pressure Vessel Technology,2004,21(9):32-36.
[25] 张洁.国内复合材料气瓶发展及气瓶标准概况[J].纤维复合材料,2007,3(3):38-42. ZHANG Jie.Development and specification summary of composite gas cylinder in China[J].Fiber Composites,2007,3(3):38-42.
[26] ZU L,KOUSSIOS S,BEUKERS A.Design of filament-wound isotensoid pressure vessels with unequal polar openings[J].Composite Structures,2009,92(9):2307-2313.
[27] ZU L,KOUSSIOS S,BEUKERS A.Shape optimization of filament wound articulated pressure vessels basedon non-geodesic trajectories[J].Composite Structures,2010,92(2):339-346.
[28] ZU L,KOUSSIOS S,BEUKERS A.Design offilament-wound domes based on the continuum theory andnon-geodesic roving trajectories[J].Composites Part A:Applied Science and Manufacturing,2010,41(9):1312-1320.
[29] ZU L,WANG J H,LI S X.Analysis of multi-layered thick-walled filament-wound hydrogen storage vessels[J].International Journal Hydrogen Energy,2014,39(36):21083-21096.
[30] ZU L,WANG J H,LI S X.Influence of fiber slippage coefficient distributions on the geometry andperformance of composite pressure vessels[J].PolymerComposites,2016,37(1):315-321.
[31] ZU L,ZHU W D,DONG H Y,et al.Application of variable slippage coefficients to the design of filament wound toroidal pressure vessels[J].Composite Structures,2017,172(3):339-344.
[32] ZU L,XU H,ZHANG B,et al.Design and production of filament-wound composite square tubes[J].Composite Structures,2018,191(5):202-208.
[33] ZHANG B,XU H,ZU L,et al.Design of filament-wound composite elbows based on non-geodesic trajectories[J].Composite Structures,2018,189(4):635-640.
[34] VAFAEESEFAT A,KHANI A.Head shape and winding angle optimization of composite pressure vessels based on a multi-level strategy[J].Applied Composite Materials,2007,14(5-6):379-391.
[35] LIU C,SHI Y Y.Design optimization for filament wound cylindrical composite internal pressure vessels considering process-induced residual stresses[J].Composite Structures,2020,235(3):111755.
[36] PARNAS L,KATIRCL N.Design of fiber-reinforced composite pressure vessels under various loading conditions[J].Composite Structures,2002,58(1):83-95.
[37] SON D S,HONG J H,CHANG S H.Determination of the autofrettage pressure and estimation of material failures of a type Ⅲ hydrogen pressure vessel by using finite element analysis[J].International Journal of Hydrogen Energy,2012,37(17):12771-12781.
[38] XU J Z,WANG L X,LIU M J,et al.Patterns design of filament wound spherical structure based on a new winding strategy[J].Journal of Reinforced Plastics and Composites,2019,38(7):314-322.
[39] MITKEVICH A B,KUL'KOV A A.Design optimization and forming methods for toroidal composite shells[J].Mechanics of Composite Materials,2006,42(2):95-108.
[40] HOJJATI M,SAFAVI A V,HOA S V.Design of domes for polymeric composite pressure vessels[J].Composite Engineering,1994,5(1):51-59.
[41][KG2.8mm] FUKUNAGA H,UEMURA M.Optimum design of helically wound composite pressure vessels[J].Composite Structures,1983,1(1):31-49.
[42] TOUGHIRY M,COUGHLIN C.NDE of composite gas cylinders[J].NTIAC Newsletter,2013,28(3):1-5.
[43] 薛彬.复合材料气瓶疲劳损伤红外检测方法研究[D].武汉:武汉工程大学,2016. XUE B.Research on infrared detection method for fatigue damage of composite gas cylinder[D].Wuhan:Wuhan Institute of Technology,2016.
[44] 杨杰.声发射信号处理与分析技术的研究[D].长春:吉林大学,2005.YANG J.Research of AE signal processing and analysis technique[D].Changchun:Jilin University,2005.
[45] LIAO B B,WANG D L,HAMDI M,et al.Acoustic emission-based damage characterization of 70 MPa type Ⅳ hydrogen composite pressure vessels during hydraulic tests[J].International Journal of Hydrogen Energy,2019,44(40):22494-22506.
[46] DAHMENE F,YAACOUBI S,MOUNTASSIR E M,et al.Towards efficient acoustic emission testing of COPV,without felicity ratio criterion,duringhydrogen-filling[J].International Journal of Hydrogen Energy,2016,41(2):1359-1368.
[47] CATTY J.Acoustic emission testing-Defining a new standard of acoustic emission testing for pressure vessels[J].Journal of Acoustic Emission,2009,27:299-313.
[48][KG2.8mm] CHOU H Y,MOURITZ A P,BANNISTER M K,et al.Acoustic emission analysis of composite pressure vessels under constant and cyclic pressure[J].Composites Part A:Applied Science and Manufacturing,2015,70(3):111-120.
[49] 李伟,付玉,蒋鹏,等.基于K均值聚类的FRP复合材料容器损伤声发射信号模式识别[J].压力容器,2014,31(8):14-19. LI W,FU Y,JIANG P,et al.Pattern recognition of acoustic emission signals of FRP composite vessel damage based on k-means clustering[J].Pressure Vessel Technology,2014,31(8):14-19.
[50] 李伟,李颖,王少凡,等.FRP复合材料容器水压爆破声发射特性分析[J].压力容器,2012,29(5):15-19. LI W,LI Y,WANG S F,et al.Analysis of acoustic emission characteristics for FRP composites vessels in hydrostatic burst test process[J].Pressure Vessel Technology,2012,29(5):15-19.
[51] LU G,ZHU T Y,XU Y M.Low velocity impact energy monitoring and recognition of composite laminates with variable thickness based on optical fiber sensor network[J].Applied Sciences,2021,11(2):584-602.
[52] MEASURES R M,GLOSSOP N D,LYMER J,et al.Structurally integrated fiber optic damage assessment system for composite materials[J].Applied Optics,1989,28(13):2626-2633.
[53] HALE K F.An optical-fibre fatigue crack-detection and monitor system[J].Smart Materials and Structures,1992,1(2):156-161.
[54] RUZEK R,KADLEC M,TSERPES K,et al.Monitoring of compressive behaviour of stiffened composite panels using embedded fibre optic and strain gauge sensors[J].International Journal of Structural Integrity,2017,8(1):134-150.
[55] MUNZKE D,DUFFNER E,EISERMANN R,et al.Monitoring of type Ⅳ composite pressure vessels withmultilayer fully integrated optical fiber based distributed strain sensing[J].Materials Today:Proceedings,2020,34(1):217-223.
[56] ERIK S,KASPAR L,FABIEN N,et al.Embedded optical fibres for monitoring pressurization andimpact of filament wound cylinders[J].Composite Structures,2018,210:608-617.
[57] KLUTE S M,METREY D R,GARY N,et al.In-situ structural health monitoring of composite-overwrapped pressure vessels[J].Sampe Journal,2016,52(2):7-17.
[58] MAURIN L,FERDINAND P,NONY F,et al.OFDRdistributed strain measurements for SHM of hydrostatic stressed structures:An application to high pressure hydrogen storage type Ⅳ composite vessels-H2E project[C]//Ewshm-7th European Workshop on Structural Health Monitoring,2014:930-937.
[59] LASN K,MULELID M.The effect of processing on the microstructure of hoop-wound composite cylinders[J].Journal of Composite Materials,2020,54(26):3981-3997.
[60] 赵海涛.基于光纤传感技术的复合材料结构全寿命健康监测研究[D].哈尔滨:哈尔滨工业大学,2008. ZHAO H T.Research on whole life health monitoring of composites structure based on fiber optic sensingtechnology[J].Harbin:Harbin Institute of Technology,2008.
[61] 肖飚,杨斌,胡超杰,等.基于埋入式应变片的纤维缠绕压力容器的健康监测[J].高压物理学报,2019,33(4):56-62. XIAO B,YANG B,HU C J,et al.Structural health monitoring of filament wound pressure vessel by embedded strain gauges[J].Chinese Journal of High Pressure Physics,2019,33(4):56-62.
[62] GHIMIRE M,WANG C,DIXON K,et al.In situ monitoring of prestressed concrete using embedded fiber loop ringdown strain sensor[J].Measurement,2018,124:224-232.
[63] CHOWDHURY N T,JOOSTEN M W,PEARCE G M K. An embedded meshing technique (SET) for analysing local strain distributions in textile composites[J].Composite Structures,2018,210:294-309.
[64][KG2.8mm] WANG Y L,WANG Y S,HAN B G,et al.Strain monitoring of concrete components using embedded carbon nanofibers/epoxy sensors[J].Construction and Building Materials,2018,186:367-378.
[65] KANERVA M,ANTUNES P,SARLIN E,et al.Direct measurement of residual strains in CFRP-tungsten hybrids using embedded strain gauges[J].Materials and Design,2017,127:352-363.
[66] YANG B,XIANG Y X,XUAN F Z,et al.Damage localization in hydrogen storage vessel by guided waves based on a real-time monitoring system[J].International Journal of Hydrogen Energy,2019,44(40):22740-22751.
[67] YANG B,XUAN F Z,XIANG Y X,et al.Lamb wave-based structural health monitoring on composite bolted joints under tensile load[J].Materials(Basel),2017,10(6):652-669.
[68] YANG B,XUAN F Z,CHEN S J,et al.Damagelocalization and identification in WGF/epoxy composite laminates by using Lamb waves:experiment and simulation[J].Composite Structures,2017,165:138-147.
[69] YANG B,XUAN F Z,LEI H S,et al.Simultaneously enhancing the IFSS and monitoring the interfacial stress state of GF/epoxy composites via building in the MWCNT interface sensor[J].Composites Part A:Applied Science and Manufacturing,2018,112:161-167.
[70] YANG B,XUAN F Z,WANG Z Q,et al.Multi-functional interface sensor with targeted IFSS enhancing,interface monitoring and self-healing of GF/EVA thermoplastic composites[J].Composites Science and Technology,2018,167:86-95.
[71] QIAO S,SHANG X C,PAN E.Characteristics of elastic waves in FGM spherical shells,an analytical solution[J].Wave Motion,2016,62:114-128.
[72] ZHANG X W,TANG Z F,LU F Z,et al.Excitation of dominant flexural guided waves in elastic hollow cylinders using time delay circular array transducers[J].Wave Motion,2016,62:41-54.
[73] 杨斌,胡超杰,轩福贞,等.多壁碳纳米管界面传感器及其在纤维缠绕压力容器原位监测中的应用[J].复合材料学报,2020,37(2):336-344. YANG B,HU C J,XUAN F Z,et al.Multi-walled carbon nanotube interfacial sensor and its application in in-situ monitoring of the filament wound pressure vessel[J].Acta Materiae Compositae Sinica,2020,37(2):336-344.
[74] 梁嫄.复合材料结构准静态压剪渐进失效机理研究[D].上海:上海交通大学,2015. LIANG Y.Progressive damage in composite structures under quasi-static punch-shear loading[D].Shanghai:Shanghai Jiao Tong University,2015.
[75] NEBE M,ASIJEE T J,BRAUN C,et al.Experimental and analytical analysis on the stacking sequence of composite pressure vessels[J].Composite Structures,2020,247:112429.
[76] 史建军,李得天.碳纤维复合材料气瓶的X射线实时成像技术[J].宇航材料工艺,2009,39(6):65-66. SHI J J,LI D T.Real-time X-ray imaging technology for carbon fiber composite cylinders[J].Aerospace Materials and Technology,2009,39(6):65-66.
[77] 黄良,金明哲,何琦,等.大容积纤维缠绕气瓶的X射线数字成像检测方法研究[J].复合材料科学与工程,2020(3):84-89. HUANG L,JIN M Z,HE Q,et al.Research on X-ray digital imaging detection method for large volume fiber-wound gas cylinder[J].Composites Science and Engineering,2020(3):84-89.
[78] 刘怀喜,张恒,马润香.复合材料无损检测方法[J].无损检测,2003,25(12):631-656. LIU H X,ZHANG H,MA R X.Nondestructive testingtechniques for composite materials[J].Nondestructive Testing,2003,25(12):631-656.