All wood based products should have been dried to ensure their stable dimension.  Indicators of stable dimension can be figured-out from wood physical properties, especially ratio of tangensial shrinkage to radial shrinkage (T/R ratio) and wood drying properties at high temperature. From those two indicators could be predicted the drying quality of wood as a basic to determine minimum – maximum of drying temperature. This research aimed to look-into the relationship between wood properties of wood and drying quality of mindi (Melia azedarach L)wood at their 5, 9, and 13 year-old trees. The preparing of test samples, and testing methods on wood physical properties covered moisture content, air-dry density, and shrinkage in tangential and radial direction, which referred to the BS 1957. Meanwhile, drying properties followed the modified Terazawa’s  method. Five classes of wood drying qualities could be derived from the analysis of T/R ratio and drying property at each tree age group. Results revealed that wood density ranged about 0.46 – 0.58 g/cm³. Drying quality of each wood (except the portion near the pith) belong to B (good) for 13 years old, C (fair) for 9 years, and D (poor) for 5 years old. Related to the drying quality, the minimum – maximum temperature  for 13 years  mindi wood was 55–85 ^oC; for 9 years was 50–80 ^oC;  and for 5 years was 40–65 ^oC. Supported by the performance of  wood surface, especially at 13 years old, mindi wood was suitable for wooden furniture.

density; T/R ratio; drying property; drying quality; minimum-maximum; temperature of drying

Barrios, A., Trincado, G., Watt, M.S. 2017. Wood properties of juvenile and mature wood of Pinus radiata D. Don trees growing on contrasting sites in Chile. Fundamental Research. For. Sci. 63 (2): 184–191. doi: 10.5849/forsci.2016-060.

Basri, E., Damayanti R., Darwis, A., Saefudin., Wahyudi, I. 2021. Anatomical properties of Hibiscus macrophyllus and its mature wood development. IAWA J. 42 (4): 475–485.

Basri, E., Saefudin. 2021. Improvement on several physical and mechanical properties of Jati Utama Nusantara wood by thermal compression treatment. J Penelit Has Hutan. 39 (3): 121–128. doi: 10.20886/jphh.2021.39.3.121-128.

Basri, E., Wahyudi, I. 2013. Wood Basic Properties of Jati Plus Perhutani from different ages and their relationships to drying properties and qualities. J. For. Prod. Res. 31 (2): 93–102 (in Indonesian). doi: 10.20886/jphh.2013.31.2.93-102.

Basri, E., Yuniarti, K., Wahyudi, I., Pari, R. 2020. Wood Drying Technology. Bogor: IPB Press. 130 pp.

BS (British Standards). 1957. Method of Testing Small Clear Specimens of Timber. BS 373. London: British Standards Institution.

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: 22–28. doi: 10.1007/s13196-015-0140-8.

Darmawan, W., Nandika, D., Afaf, B.D.H., Rahayu, I., Lumongga, D. 2018. Radial variation in selected wood properties of Indonesian Merkusii Pine. J. Korean Wood Sci. Technol. 46 (4): 323–337. doi: 10.5658/WOOD.2018.46.4.323.

Darmawan, W., Nandika, D., Kartikasari, R., Sitompul, A., Rahayu, I., Gardner, D. 2015. Juvenile and mature wood characteristics of short and long rotation teak in Java. IAWA J. 36 (4): 429–443. doi: 10.1163/22941932-20150112.

Dishut Jatim (Dinas Kehutanan Provinsi Jawa Timur). 2023. Mindi (Melia azedarach). UPT Perbenihan Tanaman Hutan. https://uptpth.dishut.jatimprov.go.id/mindi-melia-azedarach/

Djarwanto, Damayanti, R., Balfas, J., Basri, E., Jasni, Sulastiningsih, I., M., … Krisdianto. 2017. Pengelompokan Jenis Kayu Perdagangan Indonesia. (I. Wahyudi, N.S.M. Saad, David, Eds.). Bogor: FORDA PRESS. Untuk Bahan Meubel dengan Metode SAW (Simple Additive Weighting). Jurnal Informatika & Rekayasa Elektronika (JIRE) 5 (2): 191-200. ISSN. 2620-6900 (Online) 2620-6897 (Cetak).

HIMKI (Himpunan Industri Mebel dan Kerajinan Indonesia. 2022. Terancamnya Ketahanan Bahan Baku. Himpunan Industri Mebel dan Kerajinan Indonesia. 11 Oktober 2022. https://www.himki-indonesia.com/post/view/394-id-terancamnya-ketahanan-bahan-baku.

Martawijaya, A., Kartasujana, I., Mandang, Y. I., Kadir, K., Prawira, S. A., 2014. Atlas Kayu Indonesia Jilid II. Bogor: Pusat Penelitian dan Pengembangan Keteknikan Kehutanan dan Pengolahan Hasil Hutan, Badan Penelitian dan Pengembangan Kehutanan, Kementerian Kehutanan.

Rambey, R. 2011. pengetahuan lokal sistem agroforestri mindi (Melia azedarach L.) (studi kasus di Desa Selawi Kecamatan Talegong, Kabupaten Garut, Provinsi Jawa Barat). Tesis. Bogor: Sekolah Pascasarjana Institut Pertanian Bogor.

Rocha, M.F.V., Veiga, T.R.L.A., Soares, B.C.D., de Araujo, A.C.C., Carvalho, A.M.M., Hein, P.R.G. 2019. Do the growing conditions of trees influence the wood properties? Floresta e Ambiente 26: 1–16. doi: 10.1590/2179-8087.035318.

Shmulsky R, Jones PD. 2019. Forest Products and Wood Science: An introduction. 7th Edition. Wiley-Blackwell, West Sussex.

SNI (Standar Nasional Indonesia). 1989. Kayu untuk mebel, syarat sifat fisik dan mekanik. SNI 01-0608- 1989. Badan Standardisasi Nasional, Jakarta.

Susanto, M., Mashudi. 2017. Growth trend of Hibiscus macrophyllus Roxb. Ex Hornem between provenances in Java.

Bioeksperimen, 4 (1): 20–28 (in Indonesian). doi: 10.23917/bioeksperimen.v4i1.3971.

Vidaurre, G.B., Vital, B.R., Oliveira, A.de C., Oliveira, J.T. da S., Moulin, J.C., Silva, J.G.M.da., Soranso, D.R. 2018. Physical and mechanical properties of juvenile Schizolobium amazonicum Wood.

Revista Árvore, 42 (1): e420101. doi: 10.1590/1806-90882018000100001.

Yuniarti, K., Basri, E. 2017. Sifat pengeringan suhu tinggi dan bagan pengeringan dasar 5 jenis kayu kurang dikenal asal Riau. J Penelit Kehutan Wallacea, 6 (2): 91–99. doi: 10.18330/jwallacea.2017.vol6iss2pp91-99.

<iframe style="width: 0; height: 0; display: