Abstract
While, for instance, oils and waxes were found to be promising for protecting wood under laboratory test conditions, long-term outdoor experience with these materials is limited. This study aimed at investigating the performance of wax-treated wood exposed aboveground in double-layer and lap-joint configurations. Wetting resistance, susceptibility to checking and durability were investigated over several years. All wax-treated wood performed better in the lap-joint exposure than in double layer, which was characterized by severe moisture trapping. However, durability and moisture performance were considerably better compared to untreated controls, but diminished with increasing exposure time. Already after 1 year of exposure, the number of cracks on lap-joint specimens was nearly identic between treated and untreated samples. Due to the wax migration observed during exposure, the formation of checks, accumulation of water in treated samples and partial infection, it can be concluded that the chosen synthetic wax types are not recommendable for practical applications. On the other hand, the principle of wood protection through moisture protection became evident in the aboveground field tests: As long as moisture exclusion was assured, the development of decay was inhibited.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amthor J (1972) Paraffindispersionen zur Hydrophobierung von Spanplatten [Paraffin dispersions fort he waterproofing of particle board]. Holz Roh Werkst 30:422–429
Augusta U, Rapp AO, Welzbacher CR, Brischke C (2005) Dauerhaftigkeit heimischer Holzarten in verschiedenen Gebrauchsklassen ohne und mit Imprägnierung durch Öle [Durability of domestic wood species in different use classes with and without oil impregantion]. In: Holzhaus-Bauweisen im Vergleich und Neues vom Holzschutz, Beiträge zum 5. Holzbauforum Leipzig. Huss-Medien, Berlin
Banks WB (1973) Water uptake by Scots pine sapwood and its restriction by the use of water repellents. Wood Sci Technol 7:271–284
Borgin K (1968) The protection of wood against dimensional instability. For S Afr 9:81–94
Brandt K, Brischke C, Melcher E, Niemeyer A, Rapp AO (2011) Untersuchung der hydrophobierenden Schutzwirkung von synthetischen Wachsen und Ölen zur Imprägnierung von Holz [Investigation of the effectiveness of impregnating wood with synthetic oils and waxes]. Final report. Institute of Wood Technology and Wood Biology, Hamburg
Brischke C, Rapp AO (2008) Dose–response relationships between wood moisture content, wood temperature and fungal decay determined for 23 European field test sites. Wood Sci Technol 42:507–518
Brischke C, Welzbacher CR, Rapp AO, Bollmus S (2006) Biozidfreier Holzschutz mit Ölen und Wachsen—Erfahrungen aus sieben Jahren Freilandversuchen zum Feuchteschutz durch Hydrophobierung [Non-biocidal wood protection with oils and waxes—Experience from 7 years field testing]. Holz-Zent.bl 132(7):206–208
CEN/TS 12037 (2003) Wood preservatives. Field test method for determining the relative protective effectiveness of a wood preservative exposed out of ground contact. Horizontal lap-joint method
EC European Commision (2012) Biocidal products regulation (BPR) 528/2012/EEC. European Commission, Strasbourg
EN 252 (1989) Field test method for determining the relative protective effectiveness of wood preservatives in ground contact
EN 350-1 (1994) Durability of wood and wood based products—natural durability of solid wood—part 1: guide to the principles of testing and classification of the natural durability of wood
EN 335 (2013) Durability of wood and wood-based products—use classes: definitions, application to solid wood and wood-based products
Evans PD, Wingate-Hill R, Cunningham RB (2009) Wax and oil emulsion additives: how effective are they at improving the performance of preservative-treated wood? For Prod J 59(1/2):66–70
Flæte PO, Høibø OA, Fjærtoft F, Nilsen TN (2000) Crack formation in unfinished siding of aspen (Populus tremula L.) and Norway spruce (Picea abies (L.) Karst.) during accelerated weathering. Holz Roh Werkst 58:135–139
Hill CA (2007) Wood modification: chemical, thermal and other processes. Wiley, New York
Hill CA (2011) Wood modification: an update. BioResources 6:918–919
Lesar B, Humar M (2011) Use of wax emulsions for improvement of wood durability and sorption properties. Eur J Wood Prod 69:231–238
Lesar B, Pavlič M, Petrič M, Škapin S, Humar M (2011) Wax treatment of wood slows photodegradation. Polym Degrad Stab 96:1271–1278
Matsuoka Y, Ohmura W, Fujiwara S, Kanagawa Y (2002) Durability of Sugi (Cryptomeria japonica D. Don) wood treated in high temperature liquid paraffin. Document No. IRG/WP 02-40221. International Research Group on Wood Preservation, Stockholm, Sweden
Müller H (1962) Erfahrungen mit Paraffin-Emulsionen als Quellschutzmittel in der Spanplattenindustrie [Experience with paraffin-wax emulsions as anti-swelling agents in chipboard industry]. Holz Roh Werkst 20:434–437
Palanti S, Feci E, Torniai AM (2011) Comparison based on field tests of three low-environmental-impact wood treatments. Int Biodeterior Biodegrad 65:547–552
Rapp AO, Augusta U (2004) The full guideline for the “double layer test method”—a field test method for determining the durability of wood out of ground. Document No. IRG/WP 04-20290. International Research Group on Wood Preservation, Stockholm, Sweden
Rapp AO, Sailer M, Peek R-D (2000) Innovative Holzvergütung zur Erhöhung der Dauerhaftigkeit [Innovative processes to improve the durability of wood]. 10. Hamburger Forst- und Holztagung, 23/24 May 2000:27–34
Rapp AO, Beringhausen C, Bollmus S, Brischke C, Frick T, Haas T, Sailer M, Welzbacher CR (2005) Hydrophobierung von Holz—Erfahrungen nach 7 Jahren Freilandtest [Hydrophobation of wood—experience after 7 years field testing]. In: 24th Holzschutztagung der DGFH, Leipzig, Germany, pp 157–170
Ringman R, Pilgård A, Brischke C, Richter K (2014) Mode of action of brown rot decay resistance in modified wood: a review. Holzforschung 68:239–246
Rypstra T, Vermaas HF, Sanderson RD (1979) Dimensional stabilisation of wood: factors influencing it and the principles of treatment. S Afr J 108:22–28
Sailer M (2000) Anwendungen von Pflanzenölimprägnierungen zum Schutz von Holz im Außenbereich [Impregnation of wood with vegetable oils for protection in outdoor applications]. Dissertation, University Hamburg
Sandberg D, Söderström O (2006) Crack formation due to weathering of radial and tangential sections of pine and spruce. Wood Mat Sci Eng 1:12–20
Scholz G, Militz H (2011) Materialeigenschaften wachsimprägnierten Holzes [Material properties of wax-impregnated wood]. Holztechnologie 52(6):29–33
Scholz G, Van den Bulcke J, Boone M, Zauer M, Bäucker E, Van Acker J, Militz H (2010a) Investigation on wax-impregnated wood. Part 1: microscopic observations and 2D x-ray imaging of distinct wax types. Holzforschung 64:581–585
Scholz G, Krause A, Militz H (2010b) Beeinflussung der Holzfestigkeit durch Wachstränkung [Impacts of wax impregnation on the strength of wood]. Holztechnologie 51(3):22–27
Scholz G, Krause A, Militz H (2010c) Exploratory study on the impregnation of Scots pine sapwood (Pinus sylvestris L.) and European beech (Fagus sylvatica L.) with different hot melting waxes. Wood Sci Technol 44:379–388
Scholz G, Adamopoulos S, Militz H (2011) Migration of blue stain fungi within wax impregnated wood. IAWA J 32(1):88–96
Stamm AJ, Hansen LA (1935) Minimizing wood shrinkage and swelling—replacing water in wood with nonvolatile materials. Ind Eng Chem 27:1480–1484
Unger A, Schniewind AP, Unger W (2001) Conservation of wood artifacts: a handbook. Springer, Belrin
Voulgaridis E (1986) Effect of water temperature and melting point of wax on water repellency in treated wood. Holzforsch Holzverwert 38:141–144
Wiertelak J, Czarnecki J (1935) Paraffin-impregnated wood—resistance to water and sulfuric acid solutions. Ind Eng Chem 27:543–547
Zahora A (2000) Long-term performance of a “wax” type additive for use with water-borne pressure preservative treatments. Document No. IRG/WP 00-40159. International Research Group on Wood Preservation, Stockholm, Sweden
Acknowledgments
The authors gratefully acknowledge support in the field trials from Karin Brandt and Andrea Niemeyer. Dr. Tobias Huckfeldt is acknowledged for characterizing fungal species from the field samples.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Brischke, C., Melcher, E. Performance of wax-impregnated timber out of ground contact: results from long-term field testing. Wood Sci Technol 49, 189–204 (2015). https://doi.org/10.1007/s00226-014-0692-6
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00226-014-0692-6