InnoFireWood
Innovative eco-efficient high fire performance wood products for demanding applications
References
[1] Östman, B. & Rydholm, D. National fire regulations in relation to the use of wood in European and some other countries. Stockholm: Swedish Institute for Wood Technology Research, 2002. 57 p. (Trätek Report P 0212044.)
[2] Östman, B., Voss, A., Hughes, A., Hovde, P. J. & Grexa, O. Durability of fire retardant treated wood at humid and exterior conditions. Review of literature. Fire and Materials, 2001. Vol. 25, No. 3, pp. 95-104.
[3] Kristoffersen, B., Steen Hansen, A., Hakkarainen, T., Östman, B., Johansson, P., Pauner, M., Grexa, O. & Hovde, P. J. Using the Cone Calorimeter for screening and control testing of fire retarded wood products. Report Nordtest project 1526-01. Trondheim: Norwegian Fire Research Laboratory, 2003. 63 p. + app. 18 p. (NBL A03119.)
[4] Evans, F. et al. Requirements for approval of fire retardant treated wood products to be used at moist conditions. Nordic Wood project P99096, 2001. (In Norwegian.)
[5] Östman, B. & Tsantaridis, L. Fire rated facade panels – Durability at climatic conditions. Stockholm: Swedish Institute for Wood Technology Research, 2000. 16 p. (Trätek Report L 0011039.) (In Swedish.)
[6] Östman, B. & Rydholm, D. National fire regulations in relation to the use of wood in European and some other countries. Stockholm: Swedish Institute for Wood Technology Research, 2002. 57 p. (Trätek Report P 0212044.)
[7] Östman, B. & Tsantaridis, L. Durability and new service classes for FRT wood in different end uses. In: Flame Retardants 2004. London, UK, 27-28 January 2004. London: Interscience Communications, 2004. Pp. 139-150. ISBN 0-9541216-2-7
[8] Nordtest method NT FIRE 053. Accelerated weathering of fire-retardant treated wood for fire testing. Nordtest, 2004.
[9] Nordtest method NT BUILD 504. Hygroscopic properties of fire-retardant treated wood and wood-based products. Espoo: Nordtest, 2003. 3 p.
[10] Östman, B. et al. Service classes for fire retardant wood. Ongoing Nordtest project no. 04150, 2005.
[11] Evans, F., Mikkola, E. & Östman, B. Corrosion from fire retardant treated wood – Round robin and a new test method. Nordtest project no. 1579-02, 2003. (In Norwegian.)
[12] Östman, B. A.-L. Fire retardant wood-fiber insulating board. Journal of Fire Sciences, 1984. Vol. 2, No. 6, pp. 454-467.
[13] LeVan, S. L. & Winandy, J. E. Effects of fire-retardant treatments on wood strength: A review. Wood and Fiber Science, 1990. Vol. 22, No. 1, pp. 113-131.
[14] Winandy, J. E. Thermal degradation of fire-retardant-treated wood: Predicting residual service life. Forest Products Journal, 2001. Vol. 51, No. 2, pp. 47-54.
[15] ASTM D 5664-02. Standard method for evaluating the effects of fire-retardant treatments and elevated temperatures on strength properties of fire-retardant treated lumber. American Society for Testing and Materials, 2002. 6 p.
[16] ASTM D 5516-03. Standard method for evaluating the mechanical properties of fire-retardant treated softwood plywood exposed to elevated temperatures. American Society for Testing and Materials, 2003. 7 p.
[17] FireRetard.com. 2003. Case Studies [web page]. [quoted 23.6.2004]. Available: http://www.fireretard.com/casestudies.html .
[18] Mikkola, E. Ignition of wood. Espoo: Technical Research Centre of Finland, 1989. 48 p. (VTT Research Notes 1057.) ISBN 951-38-3589-8 (In Finnish.)
[19] Mikkola, E. & Wichman, I. S. On the thermal ignition of combustible materials. Fire and Materials, 1989. Vol. 14, No. 3, pp. 87-96.
[20] ISO 5660-1. Reaction-to-fire tests – Heat release, smoke production and mass loss rate – Part 1: Heat release rate (cone calorimeter method). Geneva: International Organization for Standardization, 2002. 39 p.
[21] Mikkola, E. Charring of wood. Espoo: Technical Research Centre of Finland, 1990. 35 p. (VTT Research Reports 689.) ISBN 951-38-3711-4.
[22] EN 1995-1-2. Eurocode 5 – Design of timber structures – Part 1-2: General – Structural fire design. European Committee for Standardization (CEN), 2004. 69 p.
[23] König, J. Notional versus one-dimensional charring rates of timber. World Conference on Timber Engineering. Lahti, Finland, 14-17 June 2004.
[24] Nussbaum, R. M. The effect of low concentration fire retardant impregnations on wood charring rate and char yield. Journal of Fire Sciences. Vol. 6, pp. 290-207.
[25] Östman, B. A.-L. & Tsantaridis, L. D. Heat release and classification of fire retardant wood products. Fire and Materials, 1995. Vol. 19, No. 6, pp. 253-258.
[26] LeVan, S. L. Chemistry of fire retardancy. In: Rowell, R. M. (ed.). The chemistry of solid wood. Washington, DC: American Chemical Society, 1984. (Advances in Chemistry Series 207.) Pp. 531-574.
[27] Sarvaranta, L. Fire retardant wood, polymer and textile materials. Espoo: Technical Research Centre of Finland, 1996. 38 p. (VTT Research Notes 1730.) ISBN 951-38-4885-X
[28] Svensson, G. & Östman, B. Leach resistant and non-toxic flame retardants for wood – Review 1983. Stockholm: Swedish Institute for Wood Technology Research, 1984. 64 p. (Wood Technology Report no. 48.) (In Swedish.)
[29] White, R. H. & Dietenberger, M. A. Flame-retardant treatments. In: Wood Handbook – Wood as an Engineering Material. Madison, WI: U.S. Department of Agriculture, Forest Service, Forest Products Laboratory, 1999. (General Technical Report FPL-GTR-113.) Pp. 17-12 – 17-13.
[30] Nussbaum, R. & Östman, B. Fire retardants for timber structures – Literature survey 1986. Stockholm: Swedish Institute for Wood Technology Research, 1987. 48 p. (Trätek Report I 8703022.) (In Swedish.)
[31] Svensson, G. Humidity-resistant flame retardants for wood. Stockholm: Swedish Institute for Wood Technology Research, 1989. 44 p. (Trätek Report I 8904016.) (In Swedish.)
[32] Sellman, L.-G., Östman, B. & Back, E. Physical and thermal data for some inorganic fire retardant chemicals. Stockholm: Swedish Institute for Wood Research, 1974. 132 p. (Meddelande, Serie B nr 284, FS B:33.) (In Swedish.)
[33] Ohtani, H., Koseki, H. & Hirano, T. Heat transfer mechanisms in materials on fire retardation. In: Yuxiang, O. & Minxiu, Z. (eds.). International Symposium on Flame Retardants Proceedings. Beijing, China, 1-5 November, 1989. Beijing: International Academic Publishers. Pp. 256-261.
[34] Porter, D., Metcalfe, E. & Thomas, M. J. K. Nanocomposite fire retardants – A review. Fire and Materials, 2000. Vol. 24, pp. 45-52.
[35] Brumer, H., Zhou, Q., Baumann, M. J., Carlsson, K. & Teeri, T. T. Activation of crystalline cellulose surfaces through the chemoenzymatic modification of xyloglucan. Journal of the American Chemical Society, 2004. Vol. 126, pp. 5715-5721.
[36] Rose, J. K. C. & Bennett, A. B. Cooperative disassembly of the cellulose-xyloglucan network of plant cell walls: parallels between cell expansion and fruit ripening. Trends in Plant Science, 1999. Vol. 4, No. 5, pp. 176-183.
[37] Zhou, Q., Greffe, L., Baumann, M. J., Malmström, E., Teeri, T. T., Brumer, H. The use of xyloglucan as a molecular anchor for the elaboration of polymers from cellulose surfaces: a general route for the design of biocomposites. Macromolecules, 2005, in press.
[38] Östman, B. Fire classification of building panels with a wooden surface. Stockholm: Swedish Institute for Wood Technology Research, 1989. (Trätek Report I 8904072.) (In Swedish.)
[39] Commission Decision of 9 September 1994 implementing Article 20 of Directive 89/106/EEC on construction products (94/611/EC). Official Journal of the European Communities No L 241. 16.9.1994. Pp. 25-29.
[40] Commission Decision of 8 February 2000 implementing Council Directive 89/106/EEC as regards the classification of the reaction to fire performance of construction products. Official Journal of the European Communities No L 50. 23.2.2000. Pp. 14-18.
[41] EN ISO 1182:2002. Reaction to fire tests for building products – Non-combustibility test. Brussels: European Committee for Standardization, February 2002. 35 p.
[42] EN ISO 1716:2002. Reaction to fire tests for building products – Determination of the heat of combustion. Brussels: European Committee for Standardization, February 2002. 29 p.
[43] EN 13823:2002. Reaction to fire tests for building products – Building products excluding floorings exposed to the thermal attack by a single burning item. Brussels: European Committee for Standardization, February 2002. 95 p.
[44] EN ISO 11925-2:2002. Reaction to fire tests – Ignitability of building products subjected to direct impingement of flame – Part 2: Single-flame source test. Brussels: European Committee for Standardization, February 2002. 28 p.
[45] EN ISO 9239-1:2002. Reaction to fire tests for floorings – Part 1: Determination of the burning behaviour using a radiant heat source. Brussels: European Committee for Standardization, January 2002. 27 p.
[46] EN 13238:2001. Reaction to fire tests for building products – Conditioning procedures and general rules for selection of substrates. Brussels: European Committee for Standardization, May 2001. 9 p.
[47] EN 13501-1:2002. Fire classification of construction products and building elements – Part 1: Classification using test data from reaction to fire tests. Brussels: European Committee for Standardization, February 2002. 41 p.
[48] Van Mierlo, R. J. M. Development of the SBI test method (Volume 1). Delft, The Netherlands: TNO Building and Construction Research, July 1998. 11 p. + app. 43 p. (TNO-report 98-CVB-R1067.)
[49] Commission Decision of 4 October 1996 establishing the list of products belonging to Classes A 'No contribution to fire' provided for in Decision 94/611/EC implementing Article 20 of Council Directive 89/106/EEC on construction products (96/603/EC). Official Journal of the European Communities No L 267. 19.10.1996. Pp. 23-26.
[50] Messerschmidt, B., Van Hees, P. & Wickström, U. Prediction of SBI (Single Burning Item) test results by means of cone calorimeter test results. In: Conference Proceedings of Interflam ’99, 8th International Fire Science & Engineering Conference. Edinburgh, UK, 29 June – 1 July 1999. Interscience Communications Ltd: London, 1999. Pp. 11-22.
[51] Hakkarainen, T. & Kokkala, M. A. Application of a one-dimensional thermal flame spread model on predicting the rate of heat release in the SBI test. Fire and Materials, 2001. Vol. 25, No. 2, pp. 61-70.
[52] Hakkarainen, T. Rate of heat release and ignitability indices in predicting SBI test results. Journal of Fire Sciences, 2001. Vol. 19, No. 4, pp. 284-305.
[53] Hansen, A. S. Prediction of heat release in the single burning item test. Fire and Materials, 2002. Vol. 26, No. 2, pp. 87-97.
[54] Saito, K., Quintiere, J. G. & Williams, F. A. Upward turbulent flame spread. Fire Safety Science – Proceedings of the 1st International Symposium. Hemisphere: New York, 1985. Pp. 75-86.
[55] Hakkarainen, T. Correlation studies of SBI and cone calorimeter test results. Interflam 2001 – Proceedings of the 9th International Conference (Vol. 1). Edinburgh, UK, 17–19 September 2001. London: Interscience Communications, 2001. Pp. 519–530.
[56] McGrattan, K. B. (ed.) Fire Dynamics Simulator (Version 4) – Technical Reference Guide. Gaithersburg, MA, USA: National Institute of Standards and Technology, 2004. 85 p. (NIST Special Publication 1018.)
[57] McGrattan, K. B. & Forney, G. P. Fire Dynamics Simulator (Version 4) – User’s Guide. Gaithersburg, MA, USA: National Institute of Standards and Technology, 2004. 90 p. (NIST Special Publication 1019.)
[58] Hietaniemi, J., Hostikka, S. & Vaari, J. FDS simulation of fire spread – Comparison of model results with experimental data. Espoo, Finland: VTT Technical Research Centre of Finland, 2004. 45 p. + app. 6 p. (VTT Working Papers 4.) ISBN 951-38-6556-8. Available: http://www.vtt.fi/inf/pdf/workingpapers/2004/W4.pdf.
[59] Hietaniemi, J., Hakkarainen, T. & Mikkola, E. Modern tools for estimating fire performance of wood based products. COST Action E29: International Symposium on Advanced Timber and Timber-Composite Elements for Buildings. Florence, Italy, 27–29 October 2004.
