[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5658/WOOD.2020.48.1.76

Flexural Properties of Heat-Treatment Samama (Anthocephalus macrophyllus) Wood Impregnated by Boron and Methyl Metacrylate

CAHYONO, Tekat Dwi (Faculty of Agriculture, University of Darussalam Ambon)
DARMAWAN, Wayan (Department of Forest Products, Faculty of Forestry, IPB University)
PRIADI, Trisna (Department of Forest Products, Faculty of Forestry, IPB University)
ISWANTO, Apri Heri (Department of Forest Product, Faculty of Forestry, Universitas Sumatera Utara)

Publication Information

Journal of the Korean Wood Science and Technology / v.48, no.1, 2020 , pp. 76-85 More about this Journal

Abstract

This study was conducted to analyze the application of boron compounds, methyl methacrylate (MMA), and heat treatment (HT) on changes in the density, moisture content, and flexural properties of samama (Anthocephalus macrophyllus) wood. Samama wood was impregnated with borax (BX) and boric acid (BA) using a pressure method at 5 atm for 4 h. Afterwards, the wood was impregnated with MMA at the same pressure and duration. Finally, the samama wood was given HT at 90 ℃ and 180 ℃. The results indicate that there was a weight gain of 93.4% in the wood impregnated using BA and MMA monomer and HT at 90 ℃. Consequently, the wood's density increased by 82.3%. Increased MOE and MOR percentages of 32.2% and 29.4%, respectively, were also found. HT at 180 ℃ degraded the wood components and MMA, and consequently, the density, MOE, and MOR also decreased. The wood impregnated by BX, BA, and MMA, and subjected to HT also had decreased moisture content (MC). This research recommends that the application of boron (BX, BA) should be combined with an MMA monomer and HT at 90 ℃ as an alternative method to improve samama wood quality. If darker color is preferable, HT should be conducted at 180 ℃.

Keywords

boron; heat treatment; impregnation; methyl metacrylate; Samama wood;

Citations & Related Records

Times Cited By KSCI : 8 (Citation Analysis)

Reference
Cited By KSCI

1	Park, Y., Park, J.-H., Yang, S.-Y., Chung, H., Kim, H., Han, Y., Chang, Y.-S., Kim, K., Yeo, H. 2016. Evaluation of physico-mechanical properties and durability of Larix kaempferi wood heat-treated by superheated steam. Journal of the Korean Wood Science and Technology 44(5): 776-784. DOI
2	Percin, O., Sofuoglu, S.D., Uzun, O. 2015. Effects of boron impregnation and heat treatment on some mechanical properties of oak (Quercus petraea Liebl.) wood. BioResources 10(3): 3963-3978.
3	Priadi, T., Sholihah, M., Karlinasari, L. 2019. Water Absorption and Dimensional Stability of Heattreated Fast-growing Hardwoods. Journal of the Korean Wood Science and Technology 47(5): 567-578. DOI
4	Romagnoli, M., Cavalli, D., Pernarella, R., Zanuttini, R., Togni, M. 2015. Physical and mechanical characteristics of poor-quality wood after heat treatment. IForest 8(6): 884-891. DOI
5	Salman, S., Petrissans, A., Thevenon, M.F., Dumarcay, S., Perrin, D., Pollier, B., Gerardin, P. 2014. Development of new wood treatments combining boron impregnation and thermo modification: effect of additives on boron leachability. European Journal of Wood and Wood Products 72(3): 355-365. DOI
6	Sandberg, D., Kutnar, A., Mantanis, G. 2017. Wood modification technologies-a review. iForest-Biogeosciences and Forestry 10(6): 895-908. DOI
7	Simsek, H., Baysal, E., Peker, H. 2010. Some mechanical properties and decay resistance of wood impregnated with environmentally-friendly borates. Construction and Building Materials 24(11): 2279-2284. DOI
8	Sites, W., Williams, L. 1997. Performance of borate treated wood coated with water repellants in Caribbean and southern US. Test structures. Proceedings Second International Conference on Wood Protection with Diffusible Preservation and Pesticides.
9	Tarmian, A., Mastouri, A. 2019. Changes in moisture exclusion efficiency and crystallinity of thermally modified wood with aging. iForest-Biogeosciences and Forestry 12(1): 92-97. DOI
10	Todaro, L., Rita, A., Negro, F., Moretti, N., Saracino, A., Zanuttini, R. 2015. Behavior of pubescent oak (Quercus pubescens Willd.) wood to different thermal treatments. IForest 8(6): 748-755. DOI
11	Toker, H., Baysal, E., Simsek, H., Senel, A., Sonmez, A., Altinok, M., Ozcifci, A., Yapici, F. 2009. Effects of some environmentally-friendly fire-retardant boron compounds on modulus of rupture and modulus of elasticity of wood. Wood Research (Bratislava) 54(1): 77-88.
12	Wang, Q., Wang, W., Winandy, J.E. 2005. Effects of a new GUP-B fire retardant on mechanical properties of Korean pine when exposed to elevated temperature. Forest Products Journal 55(12): 214.
13	Cahyono, T.D., Wahyudi, I., Priadi, T., Febrianto, F., Darmawan, W., Bahtiar, E. T., Ohorella, S., Novriyanti, E. 2015. The quality of 8 and 10 years old samama wood (Anthocephalus macrophyllus). J Indian Acad Wood Sci 12(1): 22-28. DOI
14	Yalinkilic, M.K., Tsunoda, K., Takahashi, M., Gezer, E.D., Dwianto, W., Nemoto, H. 1998. Enhancement of biological and physical properties of wood by boric acid-vinyl monomer combination treatment. Holzforschung 52(6): 667-672. DOI
15	ASTM 2010. Standard test methods for direct moisture content measurements of wood and wood-base materials (ASTM D4442-92). American Society for Testing and Materials, ASTM International, West Conshohocken, Pennsylvania.
16	Awoyemi, L., Westermark, U. 2005. Effects of borate impregnation on the response of wood strength to heat treatment. Wood Science and Technology 39(6): 484-491. DOI
17	Biziks, V., Van Acker, J., Militz, H., Grinins, J., Van den Bulcke, J. 2019. Density and density profile changes in birch and spruce caused by thermohydro treatment measured by X-ray computed tomography. Wood Science and Technology 53(2): 491-504. DOI
18	Bowyer, J.L., Shmulsky, R., Haygreen, J.G. 2007. Forest products and wood science: an introduction. Wiley-Blackwell Publishing, Ames. Iowa(US).
19	Cahyono, T.D., Ohorella, S., Febrianto, F. 2012. Beberapa Sifat Kimia dan Keawetan Alami Kayu Samama (Antocephallus macrophyllus) terhadap rayap tanah. Ilmu dan Teknologi Kayu Tropis 10(2): 168-178.
20	Cahyono, T.D., Wahyudi, I., Priadi, T., Febrianto, F., Bahtiar, E.T., Novriyanti, E. 2016. Analysis on Wood Quality, Geometry Factor, and Their Effects on Lathe Check of Samama (Anthocephalus macrophyllus) Veneer. Journal of the Korean Wood Science and Technology 44(2): 828-841. DOI
21	Can, A., Yildiz, S., Yildiz, C.U., Tomak, D.E. 2010. Effects of boron impregnation and heat treatment on some physical and mechanical properties of spruce and pine wood.
22	Chang, Y.-S., Han, Y., Eom, C.-D., Jeon, S., Yeo, H. 2019. Hygroscopic Property of Heat Treated Yellow Poplar (Liriodendron tulipifera) Wood. Journal of the Korean Wood Science and Technology 47(6): 761-769. DOI
23	Chaouch, M., Petrissans, M., Petrissans, A., Gerardin, P. 2010. Use of wood elemental composition to predict heat treatment intensity and decay resistance of different softwood and hardwood species. Polymer Degradation and Stability 95(12): 2255-2259. DOI
24	JAS 2003. Japanese Agricultural Standard for Structural Laminated Veneer Lumber. JAS: SE-11 No. 237. Japanese Agricultural Standar Association, Japan.
25	Esteves, B., Pereira, H. 2008. Wood modification by heat treatment: A review. BioResources 4(1): 370-404. DOI
26	Gaff, M., Babiak, M., Kacik, F., Sandberg, D., Turcani, M., Hanzlik, P., Vondrova, V. 2019. Plasticity properties of thermally modified timber in bending-The effect of chemical changes during modification of European oak and Norway spruce. Composites Part B: Engineering 165: 613-625. DOI
27	Hadi, Y.S., Nurhayati, T., Yamamoto, H. 2007. Ketahanan Kayu Termodifikasi Kimia terhadap Biodeteriorasi: Studi pada Kayu Asap dan Kayu Asetilasi, Bogor (ID).
28	Kartal, S., Yoshimura, T., Imamura, Y. 2004. Decay and termite resistance of boron-treated and chemically modified wood by in situ co-polymerization of allyl glycidyl ether (AGE) with methyl methacrylate (MMA). International biodeterioration & biodegradation 53(2): 111-117. DOI
29	Kartal, S.N., Hwang, W.-J., Imamura, Y. 2008. Combined effect of boron compounds and heat treatments on wood properties: Chemical and strength properties of wood. Journal of Materials Processing Technology 198(1-3): 234-240. DOI
30	Kim, Y.K., Kwon, G.J., Kim, A.R., Lee, H.S., Purusatama, B., Lee, S.H., Kang, C.W., Kim, N.H. 2018. Effects of Heat Treatment on the Characteristics of Royal Paulownia (Paulownia tomentosa (Thunb.) Steud.) Wood Grown in Korea. Journal of the Korean Wood Science and Technology 46(5): 511-526. DOI
31	Missio, A.L., de Cademartori, P.H.G., Mattos, B.D., Santini, E.J., Haselein, C.R., Gatto, D.A. 2016. Physical and mechanical properties of fast-growing wood subjected to freeze-heat treatments. BioResources 11(4): 10378-10390.
32	Mohared, A., Van Acker, J., Stevens, M. 2002. Effect of protective additives on leachability and efficacy of borate treated wood. IRG/WP 02-30290. IRG Secretariat, Stockholm, Sweden.