Your search keyword '"Palanti, Sabrina"' showing total 5 results

1. Tannin-caprolactam and Tannin-PEG formulations as outdoor wood preservatives: biological properties

Author

Hu, Jinbo, Thevenon, Marie-France, Palanti, Sabrina, and Tondi, Gianluca

Published

2017

2. Modelling the Material Resistance of Wood—Part 3: Relative Resistance in above- and in-Ground Situations—Results of a Global Survey

Author

Brischke, Christian, Alfredsen, Gry, Humar, Miha, Conti, Elena, Cookson, Laurie, Emmerich, Lukas, Flæte, Per Otto, Fortino, Stefania, Francis, Lesley, Hundhausen, Ulrich, Irbe, Ilze, Jacobs, Kordula, Klamer, Morten, Kržišnik, Davor, Lesar, Boštjan, Melcher, Eckhard, Meyer-Veltrup, Linda, Morrell, Jeffrey J., Norton, Jack, Palanti, Sabrina, Presley, Gerald, Reinprecht, Ladislav, Singh, Tripti, Stirling, Rod, Venäläinen, Martti, Westin, Mats, Wong, Andrew H.H., and Suttie, Ed

Subjects

dose–response model, fungal decay, Moisture performance, Water uptake and release, Biological durability, biological durability, service life prediction, Wetting ability, moisture performance, Moisture dynamics, water uptake and release, Fungal decay, QK900-989, Dose–response model, Plant ecology, moisture dynamics, wetting ability, Service life prediction

Abstract

Durability-based designs with timber require reliable information about the wood properties and how they affect its performance under variable exposure conditions. This study aimed at utilizing a material resistance model (Part 2 of this publication) based on a dose–response approach for predicting the relative decay rates in above-ground situations. Laboratory and field test data were, for the first time, surveyed globally and used to determine material-specific resistance dose values, which were correlated to decay rates. In addition, laboratory indicators were used to adapt the material resistance model to in-ground exposure. The relationship between decay rates in-and above-ground, the predictive power of laboratory indicators to predict such decay rates, and a method for implementing both in a service life prediction tool, were established based on 195 hardwoods, 29 softwoods, 19 modified timbers, and 41 preservative-treated timbers.

Published

2021

3. Modeling the material resistance of wood—part 2:Validation and optimization of the meyer-veltrup model

Author

Brischke, Christian, Alfredsen, Gry, Humar, Miha, Conti, Elena, Cookson, Laurie, Emmerich, Lukas, Flæte, Per-Otto, Fortino, Stefania, Francis, Lesley, Hundhausen, Ulrich, Irbe, Ilze, Jacobs, Kordula, Klamer, Morten, Krzisnik, Davor, Lesar, Bostjan, Melcher, Eckhard, Meyer-Veltrup, Linda, Morell, Jeffrey, Norton, Jack, Palanti, Sabrina, Presley, Gerald, Reinprecht, Ladislav, Singh, Tripti, Stirling, Rod, Venalainen, Martti, Westin, Mats, Wong, Andrew, and Suttie, Ed

Subjects

fungal decay, Moisture performance, biological durability, dose-response model, moisture dynamics, moisture performance, service life prediction, water uptake and release, wetting ability, Water uptake and release, Biological durability, Wetting ability, Moisture dynamics, Fungal decay, QK900-989, Plant ecology, Dose-response model, Service life prediction

Abstract

Service life planning with timber requires reliable models for quantifying the effects of exposure-related parameters and the material-inherent resistance of wood against biotic agents. The Meyer-Veltrup model was the first attempt to account for inherent protective properties and the wetting ability of wood to quantify resistance of wood in a quantitative manner. Based on test data on brown, white, and soft rot as well as moisture dynamics, the decay rates of different untreated wood species were predicted relative to the reference species of Norway spruce (Picea abies). The present study aimed to validate and optimize the resistance model for a wider range of wood species including very durable species, thermally and chemically modified wood, and preservative treated wood. The general model structure was shown to also be suitable for highly durable materials, but previously defined maximum thresholds had to be adjusted (i.e., maximum values of factors accounting for wetting ability and inherent protective properties) to 18 instead of 5 compared to Norway spruce. As expected, both the enlarged span in durability and the use of numerous and partly very divergent data sources (i.e., test methods, test locations, and types of data presentation) led to a decrease in the predictive power of the model compared to the original. In addition to the need to enlarge the database quantity and improve its quality, in particular for treated wood, it might be advantageous to use separate models for untreated and treated wood as long as the effect of additional impact variables (e.g., treatment quality) can be accounted for. Nevertheless, the adapted Meyer-Veltrup model will serve as an instrument to quantify material resistance for a wide range of wood-based materials as an input for comprehensive service life prediction software.

Published

2021

4. Tannin-caprolactam and Tannin-PEG formulations as outdoor wood preservatives: biological properties.

Author

Jinbo Hu, Thevenon, Marie-France, Palanti, Sabrina, and Tondi, Gianluca

Abstract

Key Message This article presents the enhancement in boron fixation as well as the improved biological resistance against fungi and termites for wood samples treated with tannin-caprolactam and tannin-PEG formulations. Context Although the recently developed tannin-boron wood preservatives have shown high biological protection, they presented also average resistance against weathering. The tannin-caprolactam formulations have shown improved weathering resistances and dimensional stability. Aims For this reason, more detailed biological tests were performed to evaluate the influence of the caprolactam and PEG on the biological resistance. Methods In this paper, the boron leaching of the tannincaprolactam and tannin-PEG impregnated Scots pine specimens was observed and the biocidal effect against fungi (Antrodia spp. and Coniophora puteana) and insects (Reticulitermes flavipes and Hylotrupes bajulus) were determined according to the guidelines of EN 113, EN 117, and EN 47. Results The advanced formulations containing PEG have shown interesting resistance against fungal decay, but very low penetration and weak resistance against larvae while the tannin-caprolactam preservatives have shown overall improved biological performances and higher boron fixations. Conclusion The biocidal activity of the caprolactam-added formulations was overall enhanced and therefore these formulations are confirmed to be an interesting alternative for the wood preservation in outdoor environment. [ABSTRACT FROM AUTHOR]

Published

2017

5. Modelling the Material Resistance of Wood—Part 2: Validation and Optimization of the Meyer-Veltrup Model.

Author

Brischke, Christian, Alfredsen, Gry, Humar, Miha, Conti, Elena, Cookson, Laurie, Emmerich, Lukas, Flæte, Per Otto, Fortino, Stefania, Francis, Lesley, Hundhausen, Ulrich, Irbe, Ilze, Jacobs, Kordula, Klamer, Morten, Kržišnik, Davor, Lesar, Boštjan, Melcher, Eckhard, Meyer-Veltrup, Linda, Morrell, Jeffrey J., Norton, Jack, and Palanti, Sabrina

Subjects

WOOD preservatives, STRENGTH of materials, WOOD, NORWAY spruce, SERVICE life, SILVER fir, CYCLIC fatigue

Abstract

Service life planning with timber requires reliable models for quantifying the effects of exposure-related parameters and the material-inherent resistance of wood against biotic agents. The Meyer-Veltrup model was the first attempt to account for inherent protective properties and the wetting ability of wood to quantify resistance of wood in a quantitative manner. Based on test data on brown, white, and soft rot as well as moisture dynamics, the decay rates of different untreated wood species were predicted relative to the reference species of Norway spruce (Picea abies). The present study aimed to validate and optimize the resistance model for a wider range of wood species including very durable species, thermally and chemically modified wood, and preservative treated wood. The general model structure was shown to also be suitable for highly durable materials, but previously defined maximum thresholds had to be adjusted (i.e., maximum values of factors accounting for wetting ability and inherent protective properties) to 18 instead of 5 compared to Norway spruce. As expected, both the enlarged span in durability and the use of numerous and partly very divergent data sources (i.e., test methods, test locations, and types of data presentation) led to a decrease in the predictive power of the model compared to the original. In addition to the need to enlarge the database quantity and improve its quality, in particular for treated wood, it might be advantageous to use separate models for untreated and treated wood as long as the effect of additional impact variables (e.g., treatment quality) can be accounted for. Nevertheless, the adapted Meyer-Veltrup model will serve as an instrument to quantify material resistance for a wide range of wood-based materials as an input for comprehensive service life prediction software. [ABSTRACT FROM AUTHOR]

Published

2021