Anticorrosive self healing coatings / Ajay Chaurasiya in PAINTINDIA, Vol. LXX, N° 9 (09/2020)  

[article]  inPAINTINDIA > Vol. LXX, N° 9 (09/2020) . - p. 56-82 Titre : Anticorrosive self healing coatings Type de document : texte imprimé Auteurs : Ajay Chaurasiya, Auteur Année de publication : 2020 Article en page(s) : p. 56-82 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Anticorrosifs Anticorrosion Catalyseurs Emulsification Métathèse (chimie) Métaux -- Revêtements protecteurs Microcapsules Monomères Nanocapsules Passivité (Chimie) Polymérisation Revêtement autoréparant Revêtements organiques Index. décimale : 667.9 Revêtements et enduits Résumé : Autonomic healing materials respond without external intervention to environmental stimuli in a nonlinear and productive fashion, and have great potential for advanced engineering systems. Self-healing coatings, which autonomically repair and prevent corrosion of the underlying substrate, are of particular interest. Notably, the worldwide cost of corrosion has been year estimated to be nearly $300 billion per year. Recent studies on self-healing polymers have demonstrated repair of bulk mechanical damage as welI as dramatic increases in the fatigue life. Non-metallic (based on polymers or oxides) and metallic protective coatings are used to protect metal products against the harmful action of the corrosion environment Various approaches for achieving healing functionality encapsulation have been demonstrated, including reversible chemistry, networks, microvascular nanoparticle phase separation, poly-ionomers, fibres hollow and separation. monomer phase. The majority of these systems, however, have serious chemical and mechanical limitations, preventing their use as coatings. Modem engineered coatings are highly optimized materials in which dramatic modifications of the coating chemistry are unlikely to be acceptable. Here, we describe a generalized approach to self-healing polymer-coating systems, and demonstrate its effectiveness for both model and industrial ly important coating systems. Note de contenu : - Definition of self-healing - Design strategies - Release of healing agents - Microcapsule embedment - Hollow fiber embedment - Microvascular system - Reversible cross-links - Diels-Alder (DA) and retro-DA reaction - Ionomers - Supramolecular polymers : Miscellaneous technologies - electrohydrodynamics - CONDUCTIVITY : Shape memory effect - Nanoparticle migrations - Co-deposition - Self-healing corrosion protection coatings polymeric coatings - Protection of mild steel - Protection of aluminium alloy - Protection of magnesium alloy - Coatings containing micro-nanocapsules - Hybrid-oxide coatings - Other self-healing coatings - Self-healing process - experimental analysis for cross cut corrosion resistance test - Others applications - Fig. 1 : Schematic representation of self-healing concept using embedded microcapsules - Fig. 2 : Light microscopic picture of encapsulated DCPD and Grubb's catalyst - Fig. 3 : Ring opening metathesis polymerization of DCPD - Fig. 4 : Optical micrographs of hollow glass fibers - Fig. 5 : Schematic representation of sel-healing concept using hollow fibers - Fig. 6 : Schematic showing self-healing materials with 3D microvascular networks - Fig. 7 : Schematic showing formation of highly cross-Iinked polymer (3M4F) using a multi-diene (four furan moieties, 4F) and multi-dienophile (three maleimide moieties, 3M) via DA reactions - Fig. 8 : Chemical structure of functionalized maleimide and furan monomers - Fig. 9 : Thermally reversible cross-linking reaction between TMI and TF through DA and retro-DA reactions - Fig. 11 : Preparation of thermally reversible polyamides - Fig. 12 : Schematic showing reversible ionic interactions - Fig. 13 : Examples of supramolecular polymers from the literature : main-chain supramolecular polymers and side-chain supramolecular polyemrs - Fig. 17 : Polymeric bis-terpyridine-metal complex (charge and anions omitted) - Fig. 18 : Schematic showing electrohydrodynamic aggregation of particles - Fig. 19 : Schematic showing conductive self-healing materials - Fig. 20 : Representative three-dimensionsl profiles of a spherical indent at load of 15 N fresh indent and after healing above the austenite finish temperature - Fig. 21 : Schematics showing electrolytic co-deposition of microcapsules (or mesoporous nanoparticles containing corrosion inhibitors) with metal ions - Fig. 22 : Schematic illustration of a crack in the epoxy coating - Fig. 23 : Schematic representation of the self-healing effect of the TiO, particle polymer composite coating - Fig. 24 : Schematic Illustration of self healing zipper-like mechanism - Fig. 25 : Schematic Self-healing mechanism of polyelectrolyte multilayers - Fig. 25 : Schematic shows how a capsule is created - Fig. 26 : Schematic shows structure of silane film - Fig. 27 : Epoxy with control, epoxy with corrosion inhibitor and epoxy with self healing additives - Fig. 28 : Schematic showing the reflow effect of self-haling clear coats En ligne : https://drive.google.com/file/d/1Z-i4m7ZBZI117NIGydOCioBCW5SAUQyz/view?usp=drive [...] Format de la ressource électronique : Pdf Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=34661 [article]

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Bulletin de liaison N° 26 / Centre Français de l'anticorrosion / Paris : CEFRACOR (2013)

Titre : Bulletin de liaison N° 26 Type de document : texte imprimé Auteurs : Centre Français de l'anticorrosion , Auteur Editeur : Paris : CEFRACOR Année de publication : 2013 Importance : 42 p. Présentation : ill. Format : 30 cm Catégories : Anticorrosion Certification Chimie des surfaces Corrosion Corrosion par l'eau de mer Métaux -- Surfaces Normalisation Passivité (Chimie) Protection cathodique Revêtements -- Corrosion Science des matériaux Surfaces (technologie) Surfaces fonctionnelles Index. décimale : 620.112 Résistance et autres propriétés des matériaux, essais non destructifs Note de contenu : - De l'ingénierie des surfaces de corrosion. Une approche systémique - Protection cathodique des ouvrages en milieu marin. Normalisation et certification du personnel pour une protection cathodique plus efficace Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=20747

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Conductive polymers as anticorrosive additive for marine coatings : a review / Umesh Wagh in PAINTINDIA, Vol. LXX, N° 9 (09/2020)  

[article]  inPAINTINDIA > Vol. LXX, N° 9 (09/2020) . - p. 84-95 Titre : Conductive polymers as anticorrosive additive for marine coatings : a review Type de document : texte imprimé Auteurs : Umesh Wagh, Auteur ; Vivek Krishnan, Auteur ; Ashok Kumar, Auteur Année de publication : 2020 Article en page(s) : p. 84-95 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Anticorrosifs Anticorrosion Conducteurs organiques Corrosion Epoxydes Métaux -- Oxydation anodique Métaux -- Revêtements protecteurs Passivité (Chimie) Polyaniline Polythiophènes Revêtements -- Additifs:Peinture -- Additifs Système de libération contrôlée (technologie) Thermogravimétrie Index. décimale : 667.9 Revêtements et enduits Résumé : Protection of metals and alloys against corrosion by using organic coatings is an area of great interest. Thus, the development of new paints attempts to improve the performance increasing their corrosion resistance and extending the fields of application. Within coating technology, there is increasing interest in the development of efficient anticorrosive additives able to replace the conventional inorganic anticorrosive pigments usually added to paints, which may have detrimental effects on both environment and health. A number of recent studies have evidenced that the modification of a paint formulation by the addition of a low concentration of conducting polymer (0.2-0.3%, w/w) increases sign ificantly the protective properties of the coating. Here we focus on the principles of anticorrosive additives based on conducting polymers for marine paints. The article reviews the most important findings achieved in recent studies. The general aim of this work is to set new standards for research and development in the paint industry by focussing on the addition of a conducting polymerto paint formulation without losing its properties and assuring a good performance. Note de contenu : - Basics of corrosion - Introduction to conductive polymers - Conventional paint system for corrosion protection - Conductive polymers (CP) based anticorrosive paints - Mechanism of corrosion protection using conducting polymers - Anodic protection mechanism - Controlled inhibitor release mechanism - Fig. 1 : Electrochemical corrosion showing rusting of plain carbon steel - Fig. 2 : Chemical structure of polythiophene and polyaniline - Fig. 3 : Outline of the redox-reactions that combines the emeraldine form and the leuco forms of polyaniline and their chemical structures - Fig. 4 : TGA curve of epoxy paint with and without corrosion inhibitors - Fig. 5 : Photographs of the painted rectangular test pieces (scale bar: 1 cm): (a) initial sample, (b) and (c) samples without and with conducting polymer, respectively, optical micrographs from the polymeric films (scale bar: 200_m) and scanning electron micrographs (scale bar: 100 _m) - Fig. 6 : Passivation of steel by conducting PANI-based paint coating - Fig. 7 : Controlled inhibitor release mechanism for a metal, M coated by a CP layer such as PANI doped with an ion, A-which acts as a corrosion inhibitor En ligne : https://drive.google.com/file/d/14IhkCrcgpw7YVYEajqQYxADflGg77zRs/view?usp=drive [...] Format de la ressource électronique : Pdf Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=34662 [article]

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Corrosion and its control in sugar industry / Raghavendra Pratap in PAINTINDIA, Vol. LXVII, N° 1 (01/2017)  

[article]  inPAINTINDIA > Vol. LXVII, N° 1 (01/2017) . - p. 89-95 Titre : Corrosion and its control in sugar industry Type de document : texte imprimé Auteurs : Raghavendra Pratap, Auteur ; Durgesh Kumar Soni, Auteur ; P. K. Kamani, Auteur Année de publication : 2017 Article en page(s) : p. 89-95 Note générale : Bibliogr. Langues : Anglais (eng) Catégories : Anticorrosifs Anticorrosion Epoxydes Métaux -- Revêtements protecteurs Passivité (Chimie) Sucre -- Industrie et commerce Surfaces -- Nettoyage Usines -- Entretien -- Gestion Index. décimale : 667.9 Revêtements et enduits Résumé : Corrosion occurs in sugar industry in various instruments and process equipments like boilers, juice extraction units, cane preparation units, heat transfer equipments etc, because of the corrosive environment created due to processing of sugar. Corrosion rates depend upon various process parameters like pH, temperature, cane juice brix, dissolved oxygen content etc. The losses due to corrosion may lead to unexpected failures, plant breakdown and poor quality & contaminated product. The remedial measures should be taken for the prevention of corrosion like application of protective coatings after the adequate surface preparation or proper selection of the materials of the process equipments. Note de contenu : - Manufacturing process of sugar - Causes of corrosion in sugar industry - Areas of corrosion in sugar industry - Corrosion of stainless steel - Passivation - Surface cleanliness - Cleaning compounds - Organic coating application in sugar industry - Types of epoxy coatings used at various sugar mills - Protection from corrosion En ligne : https://drive.google.com/file/d/1tMdvcOR6f5RQjhgPeCnBzEzbL5W6NfAe/view?usp=drive [...] Format de la ressource électronique : Pdf Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=28032 [article]

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Effect of passivation treatment and storing on adhesion and protective properties of lacquered tinplate cans / J. M. Bastidas in JOURNAL OF COATINGS TECHNOLOGY (JCT), Vol. 69, N° 871 (08/1997)

[article]  inJOURNAL OF COATINGS TECHNOLOGY (JCT) > Vol. 69, N° 871 (08/1997) . - p. 67-75 Titre : Effect of passivation treatment and storing on adhesion and protective properties of lacquered tinplate cans Type de document : texte imprimé Auteurs : J. M. Bastidas, Auteur ; J. M. Cabanes, Auteur ; R. Catala, Auteur Année de publication : 1997 Article en page(s) : p. 67-75 Note générale : Bibliogr. Langues : Américain (ame) Catégories : Adhésion Aliments -- Emballages Anticorrosion Can coating Emballages métalliques Oxydes de chrome Passivité (Chimie) Vernis Index. décimale : 667.9 Revêtements et enduits Résumé : Tinplate cans internally coated with three commercial lacquer systems were studied. The relationship found between lacquer adhesion, metallic chromium (CrM), chromium oxide (CrOx), and total chromium (CrT) existing in the passivated layer was : adhesion=CrM+10 (CrOx/CrT). The study was completed by conducting electrochemical impedance spectroscopy (EIS) and direct current (DC) polarization experiments up to 410 days. A dilute acetic acid-sodium chloride solution was used as electrolytic and a full opened can was used as the working electrode and an electrolyte cell. Iron dissolution was determined by atomic absorption spectrophotometry (AAS). The EIS, DC, and AAS techniques gave similar results. Passivation treatment did not substantially affect the porosity results. Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=18264 [article]

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Effet de la composition chimique de la solution interstitielle de bétons jeunes sur la passivation d'un acier doux / sara Chakri in MATERIAUX & TECHNIQUES, Vol. 103, N° 2 (2015)  

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Elucidation of corrosion failure mechanisms of coated phosphated steel substrates / Sarjak Amin in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 5, N° 3 (09/2008)  

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Etude électrochimique et spectrométrique de films de passivation formés sur des aciers inoxydables. Mesure d'adhésion / François Gaillard / 1983

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Évolution des méthodes et outils de recherche sur la corrosion / Philippe Marcus in MATERIAUX & TECHNIQUES, Vol. 99, N° 1 (2011)  

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Prepare hot-dip galvanized coating surfaces for painting / Thomas J. Langill in JOURNAL OF PROTECTIVE COATINGS & LININGS (JPCL), Vol. 33, N° 1 (01/2016)

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Protection for high flyers / Peter Visser in EUROPEAN COATINGS JOURNAL (ECJ), N° 12/2010 (12/2010)  

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Protection layer by layer in INTERNATIONAL SURFACE TECHNOLOGY (IST), Vol. 11, N° 3 (2018)

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Safe solvent adhesive compounding / Marzio Rota in ADHESIVE TECHNOLOGY, Vol. 15, N° 1 (03/1998)

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A study on the preparation of passivating surface using bi-layer of nanostructured ZnO and silane functionalized polymer: an alternate option to chromate passivating coating / Ashok Kumar Gupta in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 19, N° 4 (07/2022)  

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