| Titre : |
Coatings mechanics to defend against the environmental elements |
| Type de document : |
texte imprimé |
| Auteurs : |
Nicholas Foley, Auteur ; Xin Li, Auteur ; Jack Johnson, Auteur |
| Année de publication : |
2020 |
| Article en page(s) : |
p. 18-27 |
| Note générale : |
Bibliogr. |
| Langues : |
Américain (ame) |
| Catégories : |
Applications extérieures
Essais d'adhésion
Essais dynamiques
Résistance à l'allongement
Résistance à la fissuration
Résistance à la traction
Résistance thermique
Revêtements -- Détérioration:Peinture -- Détérioration
Revêtements -- Effets du climat:Peinture -- Effets du climat
Revêtements -- Effets de la température:Peinture -- Effets de la température
Revêtements -- Fissuration:Peinture -- Fissuration
Statistique
Test d'immersion
|
| Index. décimale : |
667.9 Revêtements et enduits |
| Résumé : |
Exterior surfaces experience degradative environmental conditions, such as intense UV exposure, rain, and temperature swings, leading to deterioration. Coatings are low-cost solutions offering decades of protection and preventing significant repair costs for buildings. The coating must withstand UV, mitigate water damage, and express the flexibility required to maintain adhesion to dimensionally unstable substrates (i.e., wood) as they undergo thermal expansion and contraction through the days and seasons.
we investigated paint film mechanics through accelerated thermal cycling grain crack and tensile testing with intent to correlate the film properties to exterior exposure data. In this article, we demonstrate that adhesion after accelerated weathering, combined with tensile elongation testing, can be used to model outdoor weathering. |
| Note de contenu : |
- EXPERIMENTAL SETUP : Adhesion testing - Accelerated thermal cycling grain crack test - Exterior exposure - Tensile elongation testing - Tensile elongation testing variables - Statistical data analysis
- RESULTS AND DISCUSSION : Exposure series - Freeze/thaw/immersion cycle accelerated testing - Tensile strength and elongation testing at room temperature - tensile strength and elongation testing at low temperature - Tensile strength and elongation testing after accelerated weathering - Adhesion after water conditioning - Developing new methods to predict grain cracking
- Table 1 : The full set of 17 paints comprising this study
- Table 2 : Comparative thermal cycling conditions
- Table 3 : Significant factors for grain cracking in MLR fitting
- Fig. 1 : Pine wood section with labels "s" for late wood and "f" for early wood annular rings
- Fig. 2 : Comparative width changes for both early and late annular rings. Negative values indicate contraction and positive values indicate expansion
- Fig. 3 : Image of cracking rating standard considered in ASTM D611. Originally from the pictorial photographic reference standards contained in the publication Pictorial Standards of Coatings Defects as published by the Federation of Societies for Coatings Technology
- Fig. 4 : Grain cracking rating after four years of exposure vs room-temperature strain at break
- Fig. 5 : Grain cracking rating after four years of exposure vs 0°C strain at break
- Fig. 6 : Grain cracking rating after 4 years exposure vs -20°C strain at break
- Fig. 7 : Grain cracking rating after 4 years exposure vs strain at break after seven day QUV
- Fig. 8 : Grain cracking rating after four years of exposure vs strain at brak after seven days in the fog box
- Fig. 9 : Grain cracking rating after four years of exposure vs adhesion after seven days fog box
- Fig. 10 : Coefficients for grain cracking rating in ML model (scaled and centered). A positive coefficient means that as the independent variable increases, the grain crack rating increases. Conversely, a negative coefficient means that the grain crack rating decreases for a given independent variable
- Fig. 11 : Observed vs predicted grain cracking rating in MLR model
- Fig. 12 : Room temperature strain at breat, after seven days QUV vs fresh sample |
| En ligne : |
https://drive.google.com/file/d/1k51AsqqgkIemn1paKlRMn5Q-1fYxOAeY/view?usp=share [...] |
| Format de la ressource électronique : |
Pdf |
| Permalink : |
https://e-campus.itech.fr/pmb/opac_css/index.php?lvl=notice_display&id=34725 |
in COATINGS TECH > Vol. 17, N° 10 (10/2020) . - p. 18-27
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Coatings mechanics to defend against the environmental elements in COATINGS TECH, Vol. 17, N° 10 (10/2020)
