{"title":"Capsule-based healing systems in composite materials: a review","authors":"S. Ilyaei, R. Sourki, Y. H. A. Akbari","doi":"10.1080/10408436.2020.1852912","DOIUrl":null,"url":null,"abstract":"Abstract Composites are used in a variety of applications due to their excellent properties. However, structural polymers are sensitive and susceptible to thermal and mechanical damage in form of micro-cracks, which are onset to grow deep within the structure where detection and repair are practically impossible. To overcome these problems, broad range of self-healing structures have emerged. This technology has led to an increase in the material’s lifetime and safety while reducing the repair and replacement costs. Capsule-based healing systems are a well-known technology that has many uses in smart protective coatings, dental composites, concrete components, and generally for polymer and fiber-reinforced composites. This article summarizes the research work on the capsule-based self-healing system over the last two decades. In this regard, after a brief introduction, various types of microencapsulation-based methods used in healing systems are classified. After explaining the manufacturing process of capsules, parameters affecting the microencapsulation quality particularly, agitation rate, core to shell weight ratio, monomer viscosity, solvent property, reaction time, temperature, pH, and U/F ratio are explained in detail. Finally, the most common healing efficiency evaluation methods are described. This review provides the reader with an overview of achievements to date, and insight into future development for industrial and engineering applications. Graphical Abstract Abbreviations 2MZ-Azine 2,4-diamino-6[-2-methyl-imidazolyl(1)]-ethyl-cis-triazine 2PhI 2-phenyl Imidazole BGE N-butyl Glycidyl Ether CAI Compression After Impact CB Carbon Black CC Compliance Calibration CNS Calcium hydroxide (Ca(OH) ) Nano-spherulites CNTs Carbon Nanotubes DCB Double Cantilever Beam DCM Dichloromethane DCPD Dicyclopentadiene DGEBA Diglycidyl Ether of Bisphenol A DTHP Diglycidyl Tetrahydro-o-Phthalate EDA Ethylenediamine ENB Ethylidene Norbornene EPA Ethyl Phenyl Acetate FCG Fatigue Crack Growing FRP Fiber-Reinforced Polymer GHS Globally Harmonized System of the Classification and Labeling of Chemicals GO Graphene Oxide HGFs Hollow Glass Fibers IPDI Isophorone Diisocyanate MBT Modified Beam Theory MCC Modified Compliance Calibration MF Melamine-Formaldehyde MWCNT Multi-Walled Carbon Nanotube NaCMC Carboxymethyl Cellulose O/W Oil-in-Water PA Phenyl Acetate PAA Phthalic Anhydride PAANa Sodium Polyacrylate PCL Polycaprolactone PCP Polycyclopentadiene PDA Polydopamine PDMS Poly (Dimethyl-Siloxane) PEA Polyetheramine PhCl Chlorobenzene PMCs Polymer Matrix Composites PMMA Poly (Methyl-Methacrylate) PMUF Poly (Melamine-Urea-Formaldehyde) PU Polyurethane PVA Polyvinyl Alcohol ROMP Ring-Opening Metathesis Polymerization SEM Scanning Electron Microscope SENB Single-Edge Notched Bending SIFs Stress Intensity Factors SWCNT Single-Wall Carbon Nanotube TDCB Trapped Double Cantilever Beam TGA Thermogravimetric Analysis UF Urea-Formaldehyde UFM UF Microcapsules W/O Water-in-Oil W/O/W Water-in-Oil-in-Water Nomenclature Healing efficiency Critical stress intensity factor (Mode I) Crack length Crack opening displacement Specimen length Specimen width Specimen thickness Critical fracture load Young's modulus Compliance Critical energy release rate (Mode-I) Internal work (Strain energy) Number of Fatigue cycles","PeriodicalId":55203,"journal":{"name":"Critical Reviews in Solid State and Materials Sciences","volume":"63 1","pages":"491 - 531"},"PeriodicalIF":8.1000,"publicationDate":"2020-12-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"7","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Critical Reviews in Solid State and Materials Sciences","FirstCategoryId":"88","ListUrlMain":"https://doi.org/10.1080/10408436.2020.1852912","RegionNum":2,"RegionCategory":"材料科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"MATERIALS SCIENCE, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 7
Abstract
Abstract Composites are used in a variety of applications due to their excellent properties. However, structural polymers are sensitive and susceptible to thermal and mechanical damage in form of micro-cracks, which are onset to grow deep within the structure where detection and repair are practically impossible. To overcome these problems, broad range of self-healing structures have emerged. This technology has led to an increase in the material’s lifetime and safety while reducing the repair and replacement costs. Capsule-based healing systems are a well-known technology that has many uses in smart protective coatings, dental composites, concrete components, and generally for polymer and fiber-reinforced composites. This article summarizes the research work on the capsule-based self-healing system over the last two decades. In this regard, after a brief introduction, various types of microencapsulation-based methods used in healing systems are classified. After explaining the manufacturing process of capsules, parameters affecting the microencapsulation quality particularly, agitation rate, core to shell weight ratio, monomer viscosity, solvent property, reaction time, temperature, pH, and U/F ratio are explained in detail. Finally, the most common healing efficiency evaluation methods are described. This review provides the reader with an overview of achievements to date, and insight into future development for industrial and engineering applications. Graphical Abstract Abbreviations 2MZ-Azine 2,4-diamino-6[-2-methyl-imidazolyl(1)]-ethyl-cis-triazine 2PhI 2-phenyl Imidazole BGE N-butyl Glycidyl Ether CAI Compression After Impact CB Carbon Black CC Compliance Calibration CNS Calcium hydroxide (Ca(OH) ) Nano-spherulites CNTs Carbon Nanotubes DCB Double Cantilever Beam DCM Dichloromethane DCPD Dicyclopentadiene DGEBA Diglycidyl Ether of Bisphenol A DTHP Diglycidyl Tetrahydro-o-Phthalate EDA Ethylenediamine ENB Ethylidene Norbornene EPA Ethyl Phenyl Acetate FCG Fatigue Crack Growing FRP Fiber-Reinforced Polymer GHS Globally Harmonized System of the Classification and Labeling of Chemicals GO Graphene Oxide HGFs Hollow Glass Fibers IPDI Isophorone Diisocyanate MBT Modified Beam Theory MCC Modified Compliance Calibration MF Melamine-Formaldehyde MWCNT Multi-Walled Carbon Nanotube NaCMC Carboxymethyl Cellulose O/W Oil-in-Water PA Phenyl Acetate PAA Phthalic Anhydride PAANa Sodium Polyacrylate PCL Polycaprolactone PCP Polycyclopentadiene PDA Polydopamine PDMS Poly (Dimethyl-Siloxane) PEA Polyetheramine PhCl Chlorobenzene PMCs Polymer Matrix Composites PMMA Poly (Methyl-Methacrylate) PMUF Poly (Melamine-Urea-Formaldehyde) PU Polyurethane PVA Polyvinyl Alcohol ROMP Ring-Opening Metathesis Polymerization SEM Scanning Electron Microscope SENB Single-Edge Notched Bending SIFs Stress Intensity Factors SWCNT Single-Wall Carbon Nanotube TDCB Trapped Double Cantilever Beam TGA Thermogravimetric Analysis UF Urea-Formaldehyde UFM UF Microcapsules W/O Water-in-Oil W/O/W Water-in-Oil-in-Water Nomenclature Healing efficiency Critical stress intensity factor (Mode I) Crack length Crack opening displacement Specimen length Specimen width Specimen thickness Critical fracture load Young's modulus Compliance Critical energy release rate (Mode-I) Internal work (Strain energy) Number of Fatigue cycles
摘要复合材料因其优异的性能而被广泛应用。然而,结构聚合物是敏感的,容易受到微裂纹形式的热损伤和机械损伤,这些微裂纹开始在结构内部深入生长,而检测和修复实际上是不可能的。为了克服这些问题,出现了各种各样的自我修复结构。这项技术提高了材料的使用寿命和安全性,同时降低了维修和更换成本。基于胶囊的愈合系统是一项众所周知的技术,在智能保护涂层、牙科复合材料、混凝土组件以及通常用于聚合物和纤维增强复合材料中有许多用途。本文综述了近二十年来基于胶囊的自愈系统的研究工作。在这方面,在简要介绍之后,对治疗系统中使用的各种类型的基于微胶囊的方法进行分类。在阐述了微胶囊的制备工艺后,详细阐述了影响微胶囊质量的参数,特别是搅拌速率、芯壳比、单体粘度、溶剂性质、反应时间、温度、pH和U/F比。最后,介绍了常用的治疗效果评价方法。这篇综述为读者提供了迄今为止的成就概述,并深入了解了工业和工程应用的未来发展。图摘要缩写2MZ-Azine 2,4-二氨基-6[-2-甲基咪唑(1)]-乙基顺式三嗪2PhI 2-苯基咪唑BGE n -丁基缩水甘油醚撞击后压缩CB炭黑CC一致性校准CNS氢氧化钙(Ca(OH))纳米球粒CNTs碳纳米管DCB双悬臂梁DCM二氯甲烷DCPD双环戊二烯二缩水甘油双酚A二氢二甲酸二缩水甘油EDA乙二胺ENB乙二烯降冰片烯EPA乙基全球化学品统一分类和标记体系氧化石墨烯中空玻璃纤维IPDI异福尔酮二异氰酸酯MBT修正束理论MCC修正一致性校准MF三聚氰胺甲醛MWCNT多壁碳纳米管NaCMC羧甲基纤维素O/W水包油PA乙酸苯酯PAA邻苯酐PAANa聚丙烯酸钠PCL聚己内酯PCP聚环戊二烯聚多巴胺聚二甲基硅氧烷聚乙胺氯苯聚醚基复合材料聚甲基丙烯酸甲酯聚三聚氰胺聚脲醛PU聚氨酯聚三聚氰胺聚脲醛聚乙烯醇开环复分解聚合扫描电镜扫描电镜单边缺口弯曲应力强度因子swcnts单壁碳纳米管捕获双悬臂梁热重分析修复效率临界应力强度因子(ⅰ型)裂纹长度裂纹张开位移试件长度试件宽度试件厚度临界断裂载荷杨氏模量柔度临界能量释放率(ⅰ型)内功(应变能)疲劳循环次数
期刊介绍:
Critical Reviews in Solid State and Materials Sciences covers a wide range of topics including solid state materials properties, processing, and applications. The journal provides insights into the latest developments and understandings in these areas, with an emphasis on new and emerging theoretical and experimental topics. It encompasses disciplines such as condensed matter physics, physical chemistry, materials science, and electrical, chemical, and mechanical engineering. Additionally, cross-disciplinary engineering and science specialties are included in the scope of the journal.