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Innovative composites made from up to 92% reclaimed materials / Ralf-Stefan Stuhr in JEC COMPOSITES MAGAZINE, N° 136 (09-10/2020)
[article]
Titre : Innovative composites made from up to 92% reclaimed materials Type de document : texte imprimé Auteurs : Ralf-Stefan Stuhr, Auteur ; Reinhard Kessing, Auteur Année de publication : 2020 Article en page(s) : p. 38-39 Langues : Anglais (eng) Catégories : Automobiles -- Matériaux
Composites à fibres de verre
Eoliennes -- Matériaux
Polyuréthanes
Procédés de fabrication
Récupération (Déchets, etc.)Index. décimale : 668.4 Plastiques, vinyles Résumé : "To get straight to the point, Infinici has developed a technology that allows us to produce new composites from EoL glass fibre-reinforced plastics (GRP) and rigid polyurethane (PUR) composite materials. At first, everyone thought we were crazy : Composites cannot be separated again... It is technically not possible... It does not pay off... There is no market for it... The list of objections was endless. Now momentum is on our side". Note de contenu : - Technology consortium
- Into new composites
- The Infinici Technology
- New high-strength composite panels from EoL wind blades and auto parts
- Fig. 1 : Materials sources for the Infinici composites production
- Fig. 2 : Infinici technology for material transformationPermalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=35458
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Code-barres Cote Support Localisation Section Disponibilité 22571 - Périodique Bibliothèque principale Documentaires Disponible Innovative cross-linking enhances efficiency and effectivity of coating processes in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 208, N° 4646 (11/2018)
[article]
Titre : Innovative cross-linking enhances efficiency and effectivity of coating processes Type de document : texte imprimé Année de publication : 2018 Article en page(s) : p. 31-32 Langues : Anglais (eng) Catégories : Dispersions et suspensions
Polyuréthanes
Réticulation (polymérisation)
Revêtements en phase aqueuse -- Séchage sous rayonnement ultravioletIndex. décimale : 667.9 Revêtements et enduits Résumé : Multi-curing waterborne polyurethane dispersion speeds up drying, cuts process times by up to half, and improves performance even under poor UV-curing conditions.
The advantages of UV-curing waterborne polyurethane (PU) coatings are well known ; their disadvantages too: insufficient UV curing in shadow areas or for pigmented paints and a lengthy water evaporation phase before UV curing can Begin, for example. Now, a new multi-curing waterborne PU dispersion developed by Covestro has been shown to overcome these problems and deliver significant benefits. This innovative technology received the Alain Clause Award at the 2018 European Technical Coatings Congress in Amsterdam.
This multi-curing technology in combination with the new multi-curing PU dispersion Bayhydrol® UV 2877 has been shown to improve the coating performance, even in such low UV dosage conditions. Even without UV curing, this technology delivers an adequate coating performance, and the properties can be clearly boosted when UV light is applied. While the inherent crosslinking of the polymer compensates for the possible lack of light, the chemical constitution of this new multi-curing technology speeds up the water release phase. This brings clear benefits.
pictogram in the labelling. What's more, the product is partly manufactured from renewable sources. Besides requiring less photoinitiator, this technology also reduces the amount of UV and drying energy needed. Covestro's new multi-curing UV-curing polyurethane dispersion is suitable for a broad range of uses, eaclear and pigmented coatings, exterior applications and parquet on site. So what innovative development made this new crosslinking solution possible ?Note de contenu : - Limitations overcome
- Practical benefits
- Oxidative curing-secondary crosslinking
- Reduced drying time
- Lower costs
- Improved robustness and line speed
- High-quality wood finishes
- FIGURES : Multi-curing possibilities - Clear wood coating performance without UV light - Multi-curing dispersion allows good performance without UV curing - Pigmented wood coating performance - Multi-curing dispersion improved performance in pigmented coatings - Multi-curing UV PUD : applications possibilitiesEn ligne : https://drive.google.com/file/d/1OQLPnQM8kTvJ74S1h-gc4EMaYBKzLkMg/view?usp=drive [...] Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=31576
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Code-barres Cote Support Localisation Section Disponibilité 20368 - Périodique Bibliothèque principale Documentaires Disponible Innovative self-initiating UV-curable polyurethane dispersions in COATINGS TECH, Vol. 17, N° 7 (07/2020)
[article]
Titre : Innovative self-initiating UV-curable polyurethane dispersions Type de document : texte imprimé Année de publication : 2020 Article en page(s) : p. 44-52 Note générale : Bibliogr. Langues : Américain (ame) Catégories : Bois -- Finition
Bois -- Revêtements
Essai de dureté
Formulation (Génie chimique)
Photoamorceurs (chimie)
Polyuréthanes
Résistance à l'humidité:Résistance à l'eau
Résistance chimique
Revêtements en phase aqueuse -- Séchage sous rayonnement ultraviolet:Peinture en phase aqueuse -- Séchage sous rayonnement ultraviolet
Revêtements organiquesIndex. décimale : 667.9 Revêtements et enduits Résumé : Waterborne (WB) UV-curable polyurethane dispersions (PUDs) are the binders of choice in many industrial wood applications. These resins are formulated with photoinitiators that absorb energy and initiate consecutive free radical-curing reactions. Traditional photoinitiators include both Type I (photo cleavage) and Type II (H- abstraction) classes, which are effective for surface curing.1 Because these products are classified as environmentally damaging (toxic to aquatic life) and can be a health hazard (suspected carcinogen), it is essential to fully react these components during curing because of potential migration of unreacted residual amounts. Such concerns are especially important considering the use of these materials for skin- or food-contact applications. New-generation UV-curable PUDs have been developed with initiating sites based on Type II photoinitiators incorporated into the backbone of the polymer. These new self-initiating (SI) polymers have been evaluated for use in industrial wood applications and benchmarked against traditional WB UV PUDs formulated with both conventional and polymeric photoinitiators. The performance of both clear and pigmented coatings has been investigated.
A series of five SI WB UV resins has been developed. These polymers are SI versions of existing WB UV resins. These WB UV resins are all acrylic/polyester polyurethane dispersion hybrids with a minimum film formation temperature (MFFT) of approximately 0 oC. Table 1 summarizes the physical properties and characteristics of the resins evaluated.Note de contenu : - INTRODUCTION : Experimental - Clear self-sealing topcoats - Panel preparation
- PROCEDURES AND RESULTS : König pendulum hardness - Boiling water resistance - Chemical/stain resistance - Scrape adhesion - Ball point pen indentation - Green print resistance - Hot print resistance - Edge soak - Plasticizer resistance - Hot and cold check resistance
- Table 1 : Physical properties and characteristics
- Table 2 : Clear self-sealing topcoat
- Table 3 : Coating performances for industrial wood finishes
- Table 4 : SI WB UV 5 reformulated with type 1 photoinitiator
- Table 5 : White self-sealing topcoat formulations
- Fig. 1 : König pendulum hardness (sec)
- Fig. 2 : Boiling water resistance
- Fig. 3 : Chemical resistance using KCMA specifications
- Fig. 4 : Chemical resistance using office furniture specifications
- Fig. 5 : Scrape adhesion in Kg passed
- Fig. 6 : Ball point pen indentation in grams passed
- Fig. 7 : Chemical resistance using KCMA specifications
- Fig. 8 : Chemical resistance using office furniture specifications
- Fig. 9 : Boiling water resistance comparison
- Fig. 10 : Scrape adhesion - Kg passed and ball point pen indentation - grams passed
- Fig. 11 : König pendulum hardness (sec)
- Fig. 12 : Chemical resistance using office furniture specifications
- Fig. 13 : König pendulum hardness (sec)
- Fig. 14 : Chemical resistance using KCMA specification
- Fig. 15 : Chemical resistance using office furniture specificationsEn ligne : https://drive.google.com/file/d/1GgVQoKGEGbyU8o-MghvmFLVAL8qfoKXu/view?usp=share [...] Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=34343
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Code-barres Cote Support Localisation Section Disponibilité 21873 - Périodique Bibliothèque principale Documentaires Disponible Inorganic/organic nanocomposite coatings : The next step in coating performance / Mark D. Soucek in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 3, N° 2 (04/2006)
[article]
Titre : Inorganic/organic nanocomposite coatings : The next step in coating performance Type de document : texte imprimé Auteurs : Mark D. Soucek, Auteur ; Z. Zong, Auteur ; A. J. Johnson Année de publication : 2006 Article en page(s) : p. 133-140 Note générale : Bibliogr. Langues : Américain (ame) Catégories : Acier L'acier est un alliage métallique utilisé dans les domaines de la construction métallique et de la construction mécanique.
L'acier est constitué d'au moins deux éléments, le fer, très majoritaire, et le carbone, dans des proportions comprises entre 0,02 % et 2 % en masse1.
C'est essentiellement la teneur en carbone qui confère à l'alliage les propriétés du métal qu'on appelle "acier". Il existe d’autres métaux à base de fer qui ne sont pas des aciers comme les fontes et les ferronickels par exemple.
AluminiumL'aluminium est un élément chimique, de symbole Al et de numéro atomique 13. C’est un métal pauvre, malléable, de couleur argent, qui est remarquable pour sa résistance à l’oxydation13 et sa faible densité. C'est le métal le plus abondant de l'écorce terrestre et le troisième élément le plus abondant après l'oxygène et le silicium ; il représente en moyenne 8 % de la masse des matériaux de la surface solide de notre planète. L'aluminium est trop réactif pour exister à l'état natif dans le milieu naturel : on le trouve au contraire sous forme combinée dans plus de 270 minéraux différents, son minerai principal étant la bauxite, où il est présent sous forme d’oxyde hydraté dont on extrait l’alumine. Il peut aussi être extrait de la néphéline, de la leucite, de la sillimanite, de l'andalousite et de la muscovite.
L'aluminium métallique est très oxydable, mais est immédiatement passivé par une fine couche d'alumine Al2O3 imperméable de quelques micromètres d'épaisseur qui protège la masse métallique de la corrosion. On parle de protection cinétique, par opposition à une protection thermodynamique, car l’aluminium reste en tout état de cause très sensible à l'oxydation. Cette résistance à la corrosion et sa remarquable légèreté en ont fait un matériau très utilisé industriellement.
L'aluminium est un produit industriel important, sous forme pure ou alliée, notamment dans l'aéronautique, les transports et la construction. Sa nature réactive en fait également un catalyseur et un additif dans l'industrie chimique ; il est ainsi utilisé pour accroître la puissance explosive du nitrate d'ammonium.
Automobiles -- Matériaux
Automobiles -- Revêtements
Entretien et réparations
Galvanisation
Huiles et graisses
Matériaux hybrides
Polyesters
Polyuréthanes
Rayonnement électronique
Rayonnement ultraviolet
Revêtement métallique
UrethanesIndex. décimale : 667.9 Revêtements et enduits Résumé : Inorganic/organic hybrid materials have considerable promise and are beginning to become a major area of research for many coating usages, including abrasion and corrosion resistance. Our primary approach is to prepare the inorganic phase in situ within the film formation process of the organic phase. The inorganic phase is introduced via sol-gel chemistry into a thermosetting organic phase. By this method, the size, periodicity, spatial positioning, and density of the inorganic phase can be controlled. An important aspect of the inorganic/organic hybrid materials is the coupling agent. The initial task of the coupling agent is to provide uniform mixing of the oligomeric organic phase with the sol-gel precursors, which are otherwise immiscible. UV-curable inorganic/organic hybrid systems have the advantages of a rapid cure and the ability to be used on heat sensitive substrates such as molded plastics. Also, it is possible to have better control of the growth of the inorganic phase using UV curing. It is our ultimate goal to completely separate the curing of inorganic and organic phases to gain complete control over the morphology, and hence optimization of "all" the coating properties. Thus far, it has been found that concomitant UV curing of the inorganic and organic phases using titanium sol-gel precursors afforded nanocomposite coatings which completely block the substrate from UV light while maintaining a transparent to visible light. Also, it has been found that the morphology of the inorganic phase is highly dependent on the concentration and reactivity of the coupling agent. DOI : 10.1007/s11998-006-0016-3 En ligne : https://link.springer.com/content/pdf/10.1007%2Fs11998-006-0016-3.pdf Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=3704
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Code-barres Cote Support Localisation Section Disponibilité 004551 - Périodique Bibliothèque principale Documentaires Disponible Intelligent polymeric surfaces through molecular self-assembly / Achin Goel in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 6, N° 1 (03/2009)
[article]
Titre : Intelligent polymeric surfaces through molecular self-assembly Type de document : texte imprimé Auteurs : Achin Goel, Auteur ; Ravi G. Joshi, Auteur ; Vijay M. Mannari, Auteur Année de publication : 2009 Article en page(s) : p. 123-133 Note générale : Bibliogr. Langues : Américain (ame) Catégories : Angle de contact
Hydrophobie
Marines (peinture)
Matériaux intelligents
Microscopie à sonde à balayage
Polymères amphiphiles
Polymères ramifiés
Polyuréthanes
Revêtements:Peinture
Systèmes moléculaires organisésIndex. décimale : 667.9 Revêtements et enduits Résumé : Recently, stimuli-responsive surfaces have gained considerable interest among coatings researchers in industry as well as in academe. To date, many switchable surfaces based on such external stimuli as temperature, electricity, pH, and many others have been designed and developed. Environmentally switchable surfaces have been among the most widely studied surfaces since they are known to exhibit smart behavior under external influence. In the present work, we report the synthesis of hydrophobic, hydrophilic, and amphiphilic polyurethane coatings with tethered hydrophilic and/or hydrophobic moieties. These coatings have been characterized and tested for mechanical properties and surface characteristics using such advanced instruments as the scanning probe microscope (SPM), dynamic contact angle analyzer (DCA), adhesion tester, and nanoindenter. The surfaces with tethered hydrophobic or hydrophilic moieties, when immersed in water, showed remarkable changes in the surface topography, hence, their dynamic surface characteristics. The amphiphilic surfaces, containing both hydrophobic and hydrophilic moieties, showed intelligent behavior in response to the external environment. The ability to tailor surfaces with predictable behavior upon exposure to the external environment opens up enormous opportunities for their potential end-use applications. DOI : 10.1007/s11998-008-9125-5 En ligne : https://link.springer.com/content/pdf/10.1007%2Fs11998-008-9125-5.pdf Format de la ressource électronique : Permalink : https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=4880
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Code-barres Cote Support Localisation Section Disponibilité 011246 - Périodique Bibliothèque principale Documentaires Disponible 011271 - Périodique Bibliothèque principale Documentaires Disponible Interfacial studies of crosslinked polyurethanes ; Part I. quantitative and structural aspects of crosslinked near film-air and film-substrate interfaces in solvent-borne polyurethanes / Anneke M. Kaminski in JOURNAL OF COATINGS TECHNOLOGY (JCT), Vol. 69, N° 872 (09/1997)
PermalinkInterfacial studies of crosslinked urethanes : Part III. Structure-property relationships in polyester waterborne polyurethanes / M. W. Urban in JOURNAL OF COATINGS TECHNOLOGY (JCT), Vol. 71, N° 888 (01/1999)
PermalinkInto the future with biopolymers / Harald Käb in KUNSTSTOFFE INTERNATIONAL, Vol. 111, N° 1 (2021)
PermalinkIntroducing isoborbide : A sustainable, safe, high performance, plant-based feedstock for coatings in SURFACE COATINGS INTERNATIONAL, Vol. 104.6 (11-12/2021)
PermalinkIntroducing isosorbide : A sustainable, safe, high performance, plant-based feedstock for coatings / Jiae Kim in SURFACE COATINGS INTERNATIONAL, Vol. 103.6 (11-12/2020)
PermalinkIntroduction to farnesene-based polyols / Herbert Chao in ADHESIVES & SEALANTS INDUSTRY (ASI), Vol. 25, N° 4 (04/2018)
PermalinkInventive routes for the preparation of waterborne acrylic polyols for 2K PU protective topcoats / David Vanaken in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 212, N° 4676 (08/2022)
PermalinkInvestigating changes in electrochemical properties when nano-silica is incorporated into an acrylic-based polyurethane clearcoat / Hamed Dastmalchian in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 9, N° 2 (03/2012)
PermalinkInvestigating the antigraffiti properties of a polyurethane clearcoat containing a silicone polyacrylate additive / Mohammad Rabea in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 8, N° 4 (07/2011)
PermalinkInvestigating the long-term effects of immersion in salt solutions on the protective properties of bio-content polyurethane coatings / Douglas J. Mills in SURFACE COATINGS INTERNATIONAL, Vol. 103.4 (07-08/2020)
PermalinkInvestigation of the behavior of organo-metallic compound and its influence on polyurethane / Y.-X. Jiang in INTERNATIONAL POLYMER PROCESSING, Vol. XXXIII, N° 2 (05/2018)
PermalinkIs the future of plastics "green" ? / Rolf Mülhaupt in KUNSTSTOFFE INTERNATIONAL, Vol. 103, N° 5 (05/2013)
PermalinkPermalinkIsocyanate free polyurethane technology for wood coating applications : approaches to reducing VOC in clearcoat formulations / Jeffrey Wexler in COATINGS TECH, Vol. 14, N° 8 (08/2017)
PermalinkIsocyanate-free routes : / Jurgen van Hollen in EUROPEAN COATINGS JOURNAL (ECJ), N° 06-07/2007 (07-08/2007)
PermalinkIsocyanurate-containing urethane adhesive with improved heat stability / C. L. Wang in ADHESIVES AGE, Vol. 37, N° 13 (12/1994)
PermalinkJoining of dissimilar materials through adhesive bonding / S. F. McCleary in ADHESIVES AGE, Vol. 38, N° 2 (02/1995)
PermalinkPermalinkA key to the future / Bernhard Klein in KUNSTSTOFFE INTERNATIONAL, Vol. 100, N° 12 (12/2010)
PermalinkPermalinkPermalinkLatent-reactive and storable / Jörg Büchner in ADHESION - ADHESIVES + SEALANTS, N° 9/2007 (09/2007)
PermalinkA leather coating with self-healing characteristics / Feifei Liang in JOURNAL OF LEATHER SCIENCE AND ENGINEERING, Vol. 2 (Année 2020)
PermalinkLeather finishing : Preparation and application of cationic organosilicone/polyurethane micro-emulsion / Shen Yiding in JOURNAL OF THE SOCIETY OF LEATHER TECHNOLOGISTS & CHEMISTS (JSLTC), Vol. 91, N° 3 (05-06/2007)
PermalinkPermalinkPermalinkLife cycle assessment study on wood coatings / Berta Vega Sanchez in EUROPEAN COATINGS JOURNAL (ECJ), N° 1 (01/2021)
PermalinkLight and well-made by sand / Michael Wilhelm in KUNSTSTOFFE INTERNATIONAL, Vol. 107, N° 11 (11/2017)
PermalinkLight stabiliser enhance colour protection / Everlight Chemical Industrial Corporation (Taipei, Taiwan) in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 206, N° 4625 (10/2016)
PermalinkLighter in the air, in the wind and on the road / Thomas Neumeyer in KUNSTSTOFFE INTERNATIONAL, Vol. 102, N° 11 (11/2012)
PermalinkLighter, stronger and cheaper carbon profiles / Jérémy Viale in JEC COMPOSITES MAGAZINE, N° 111 (03/2017)
PermalinkLighter than water / Birgit Meyer in JEC COMPOSITES MAGAZINE, N° 74 (07-2012)
PermalinkLightweight construction for heavyweights / Lars-Fredrik Berg in KUNSTSTOFFE INTERNATIONAL, Vol. 112, N° 4 (2022)
PermalinkLightweight material with class A surface / Christoph Bauernfeind in KUNSTSTOFFE INTERNATIONAL, Vol. 106, N° 3 (03/2016)
PermalinkLinear glycidyl carbamate (GC) resins for highly flexible coatings / Umesh D. Harkal in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 10, N° 2 (03/2013)
PermalinkPermalinkLonger lasting, not stressing the environment / Jürgen Lippemeier in EUROPEAN COATINGS JOURNAL (ECJ), N° 03/2010 (03/2010)
PermalinkPermalinkLow monol polyether polyols offer new opportunities for sealant manufacturers / Curt Reichel in ADHESIVES AGE, Vol. 40, N° 1 (01/1997)
PermalinkLow-viscosity, high-functionality crosslinker / Christoph Irle in EUROPEAN COATINGS JOURNAL (ECJ), N° 11 (11/2015)
PermalinkLuminous fibers as design elements in plastics parts / Franz Dziuba in KUNSTSTOFFE INTERNATIONAL, Vol. 108, N° 12 (12/2018)
PermalinkA macroscopically nondestructive method for characterizing surface mechanical properties of polymeric coatings under accelerated weathering / Ching-Hsuan Chang in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 15, N° 5 (09/2018)
PermalinkMajor challenges for the polyurethane industry in the composite market / Anabel Crespo in JEC COMPOSITES MAGAZINE, N° 91 (08-09/2014)
PermalinkMaking ecological PU coatings a reality / Georg Michels in EUROPEAN COATINGS JOURNAL (ECJ), N° 7-8 (07-08/2022)
PermalinkMaking a splash / Ulrike Maassen in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 192, N° 4453 (06/2002)
PermalinkMarine biofouling inhibition by polyurethane conductive coatings / Jer-Ruey Huang in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 7, N° 1 (01/2010)
PermalinkPermalinkDes matériaux d'avenir in CAOUTCHOUCS & PLASTIQUES, N° 726 (10/1993)
PermalinkMDI-based PU coatings / Erik Merckx in EUROPEAN COATINGS JOURNAL (ECJ), N° 4/97 (04/1997)
PermalinkMeasurements of elastic properties of some coating materials / K. C. Paul in SURFACE COATINGS INTERNATIONAL. PART B : COATINGS TRANSACTIONS, Vol. 87, B1 (02/2004)
PermalinkMechanical properties of UV-waterborne varnishes reinforced by cellulose nanocrystals / Vahe Vardanyan in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 11, N° 6 (11/2014)
PermalinkMechanical vs. adhesive bonds in assembly / Antoine Curet in ADHESIVES & SEALANTS INDUSTRY (ASI), Vol. 20, N° 10 (10/2013)
PermalinkPermalinkMelt spinning of thermoplastic polyurethane - solvent-free alternative conventional solution spinning process / Pavan Kumar Manvi in CHEMICAL FIBERS INTERNATIONAL, Vol. 69, N° 4 (12/2019)
PermalinkMelt spinning of thermoplastic polyurethane solvent-free alternative to conventional solution spinning process / Pavan Kumar Manvi in CHEMICAL FIBERS INTERNATIONAL, Vol. 70, N° 4 (12/2020)
PermalinkMelt-spun elastic yarns - a game changer on the elastane market / Jan Thiel in CHEMICAL FIBERS INTERNATIONAL, (10/2021)
PermalinkMercury-free polyurethane adhesives / Frank Tran in ADHESIVES & SEALANTS INDUSTRY (ASI), Vol. 17, N° 7 (07/2010)
PermalinkMeter/mix/dispensing for polyurethane elastomeres / David Mandeville in ADHESIVES & SEALANTS INDUSTRY (ASI), Vol. 19, N° 9 (09/2012)
PermalinkMethanol degradation mechanisms and permeability phenomena in novolac epoxy and polyurethane coatings / Ting Wang in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 18, N° 3 (05/2021)
PermalinkMicro needles as biological sensors / Natalie Salk in KUNSTSTOFFE INTERNATIONAL, Vol. 99, N° 2/2009 (02/2009)
PermalinkMicrocellular thermosetting polyurethane foams / C. Brondi in INTERNATIONAL POLYMER PROCESSING, Vol. XXXV, N° 3 (07/2020)
PermalinkMicrostructure and tribological properties of TPU/fluoropolymer composites / K. Rohm in INTERNATIONAL POLYMER PROCESSING, Vol. XXXV, N° 5 (11/2020)
PermalinkMinimization of industrial wastes-adding value to collagenic : Adding value to collagenic materials procter memorial lecture / J. Cot in JOURNAL OF THE SOCIETY OF LEATHER TECHNOLOGISTS & CHEMISTS (JSLTC), Vol. 87, N° 3 (05-06/2003)
PermalinkPermalinkModélisation d'un siège typique de voiture / S. Belouettar in MATERIAUX & TECHNIQUES, Vol. 94, N° 3 (2006)
PermalinkModern 2K PU waterborne / Robert Reyer in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 203, N° 4580 (01/2013)
PermalinkModern 2K PU waterborne coatings : Environment-friendly efficiently and with high-performance / Robert Reyer in DOUBLE LIAISON, N° 592 (05/2013)
PermalinkModern bio-based wood coatings - potential for the future / Ewelina Depczynska in SURFACE COATINGS INTERNATIONAL, Vol. 102.2 (04-05/2019)
PermalinkModern design enabled by greener, cleaner sealant technology / Brian R. White in ADHESIVES & SEALANTS INDUSTRY (ASI), Vol. 26, N° 11 (11/2019)
PermalinkModification of polyurethane finishing agent using collagen hydrolysate from chrome shavings / Keyong Tang in JOURNAL OF THE AMERICAN LEATHER CHEMISTS ASSOCIATION (JALCA), Vol. CV, N° 1 (01/2010)
PermalinkModified alkyd emulsions for waterborne coatings / Carolin Wallenhorst in POLYMERS PAINT COLOUR JOURNAL - PPCJ, Vol. 206, N° 4616 (01/2016)
PermalinkMoisture curable polyurethane technology fo wood coatings / Mrunal Vaidya in PAINTINDIA, Vol. LXXI, N° 7 (07/2021)
PermalinkMoisture-cured polyurethanes - High performance surface-tolerant economical solution for heavy duty protective coatings / Prashant Gangwar in PAINTINDIA, Vol. LXI, N° 10 (10/2011)
PermalinkMoisture cured urethane coatings - A review / Shashidhar Dayanand Thoutu in PAINTINDIA, Vol. LXIV, N° 4 (04/2014)
PermalinkMoisture-permeable polyurethanepressure-sensitive adhesive addresses needs of wearable devices / Makito Nakamura in ADHESIVES & SEALANTS INDUSTRY (ASI), Vol. 27, N° 5 (05/2020)
PermalinkMolecular relaxation phenomena during accelerated weathering of a polyurethane coating / B. M. Dilhan Fernando in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 5, N° 1 (03/2008)
PermalinkPermalinkPermalinkMorphology and thermal behavior of TPU/PP blends modified with maleic anhydride grafted SEBS-g-MA block copolymer / Vesna Ocelic Bulatovic in INTERNATIONAL POLYMER PROCESSING, Vol. XXXII, N° 1 (03/2017)
PermalinkMotion sensing light guides / Mohammadreza Naeimirad in KUNSTSTOFFE INTERNATIONAL, Vol. 112, N° 3 (2022)
PermalinkLes mousses polymères poreuses : un avenir prometteur pour l'ingénierie chimique / David Edouard in L'ACTUALITE CHIMIQUE, N° 479 (12/2022)
PermalinkMS sealants : A comparative study of performance properties / Allan Hutchinson in ADHESIVES AGE, Vol. 39, N° 4 (04/1996)
PermalinkMultiplast's C Class made of TPT / Guillaume Kemlin in JEC COMPOSITES MAGAZINE, N° 84 (10/2013)
PermalinkNano-cerium dioxide synergistic potential on abrasion resistance and surface properties of polyurethane-nanocomposite coatings for esthetic and decorative applications on wood / Akbar Mastouri Mansourabad in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 17, N° 6 (11/2020)
PermalinkNanosan nanofibers represent the next breakthrough in anti-pollution treatments / Laura Frazier in SOFW JOURNAL, Vol. 143, N° 10 (10/2017)
PermalinkNanoscale protection for high-performance / Atman Fozdar in EUROPEAN COATINGS JOURNAL (ECJ), N° 7-8 (07-08/2019)
PermalinkNanosilica particle technology in solventborne, high gloss 2-pack PUR clear coats for plastics / Marco Heuer in DOUBLE LIAISON, N° 597 (03/2014)
PermalinkNanosilica reinforced waterborne siloxane-polyurethane nanocomposites prepared via "click" coupling in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 11, N° 4 (07/2014)
PermalinkNanostructured and hollow polyurethane dispersions / A. Lubnin in SURFACE COATINGS INTERNATIONAL. PART B : COATINGS TRANSACTIONS, Vol. 89, B3 (09/2006)
PermalinkNanotechnology-enhanced biocomposites for greener technologies / Özgür Seydibeyoglu in JEC COMPOSITES MAGAZINE, N° 79 (03/2013)
PermalinkPermalinkNatural and synthetic clay-filled coatings for insulation barrier applications / Roy T. Fox in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 13, N° 1 (01/2016)
PermalinkNatural coatings for natural substrates / Niek Zweep in EUROPEAN COATINGS JOURNAL (ECJ), N° 1 (01/2014)
PermalinkPermalinkNatural polyhydroxy resins in surface coatings : a review in JOURNAL OF COATINGS TECHNOLOGY AND RESEARCH, Vol. 19, N° 3 (05/2022)
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