References
- Aira, J. R. (2013) Análisis Experimental y por el Método de los Elementos Finitos del Estado de Tensiones en Uniones Carpinteras de Empalme de Llave. Universidad Politécnica de Madrid.
- Anagnostou, G. (2018) The influence of traditional Japanese timber design and construction techniques on contemporary architecture and its relevance to modern timber construction. Gottstein Fellowship Report, (October), 1–107.
- ASTM International (2019) ASTM A36/A36M-19, Standard Specification for CArbon Structural Steel.
- Branco, J. M. and Descamps, T. (2015) Analysis and strengthening of carpentry joints. Construction and Building Materials, 97, 34–47.
- Cabrero, J. (2013) Japón, un mundo en donde la madera es sagrada. Navarra Forestal, 33, 34–36.
- Cohen, D., McKay, S., Brock, L., Cole, R., Prion, H. and Barrett, D. (1996) Wood construction in Japan: past and present. Forest Products Journal, 46(11/12), 18–24.
- El-Houjeyri, I., Thi, V. D., Oudjene, M., Khelifa, M., Rogaume, Y., Sotayo, A. and Guan, Z. (2019) Experimental investigations on adhesive free laminated oak timber beams and timber-to-timber joints assembled using thermo-mechanically compressed wood dowels. Construction and Building Materials, 222(2019), 288–299.
- Esteban, M., Arriaga, F., Íñiguez, G., Bobadilla, I. and Mateo, R. (2010) The effect of fissures on the strength of structural timber. Materiales de Construccion, 60(299), 115–132.
- FAO (2021) Forest Product (Rome, Italy: Food and Agriculture Organization of the United Nations).
- Heesterman, M. and Sweet, K. (2018) Robotic Connections: Customisable Joints for Timber Construction. In: 22th conference of the iberoamerican society of digital graphics. 644–652.
- Hermoso, E., Mateo, R., Íñiguez-González, G., Montón, J. and Arriaga, F. (2016) Visual grading and structural properties assessment of large cross-section pinus radiata D. Don Timber. BioResources, 11(2), 5312–5321.
- Hill, C. A. S. and Dibdiakova, J. (2016) The environmental impact of wood compared to other building materials. International Wood Products Journal, 7(4), 215–219.
- INFOR (2020a) Chilean Statistical Yearbook of Forestry 2020 (Santiago: Chile).
- INFOR (2020b) Elaboración en la Industria del Aserrío en Chile (Santiago: Chile).
- INN (1986) NCh 987: Wood - Determination of mechanical properties - Static bending test.
- INN (2005) NCh1207 - Pino radiata, Pino oregón, Pino ponderosa - Clasificación visual para uso estructural - Especificaciones de los grados de calidad.
- INN (2014) NCh 1198: Wood - Wood buildings - Calculation and design.
- Jayawickrama, K. J. S. (2001) Breeding radiata pine for wood stiffness: review and analysis. Australian Forestry, 64(1), 51–56.
- Jeong, G. Y. (2020) Tensile properties of utgulisanji connection. International Journal of Architectural Heritage, 15(2), 313–320.
- Karolak, A., Jasienko, J., Nowak, T. and Raszczuk, K. (2020a) Experimental investigations of timber beams with stop-splayed scarf carpentry joints. Materials, 13(6), 1–16.
- Karolak, A., Jasieńko, J. and Raszczuk, K. (2020b) Historical scarf and splice carpentry joints: state of the art. Heritage Science, 8(1), 1–19.
- Keenan, F. J. (1974) Shear strength of wood beams. Forest Products Journal, 24(9), 63–70.
- Landa-Esparza, M. and Landa Esparza, M. (1999) Nuevas técnicas de reparación de estructuras de madera. Elementos flexionados. aporte de madera -unión encolada II. metodología de puesta en obra. RE: Revista de Edificación, 29, 30–36.
- Laurent, A., Van der Meer, Y. and Villeneuve, C. (2018) Comparative life cycle carbon footprint of a Non-residential steel and wooden Building structures. Current Trends Forest Research, 2018(4), 1–10.
- Li, H., Lam, F. and Qiu, H. (2017) Flexural performance of spliced beam connected and reinforced with self-tapping wood screws. Engineering Structures, 152, 523–534.
- Li, X., Ashraf, M., Subhani, M., Kremer, P., Kafle, B. and Ghabraie, K. (2020) Experimental and numerical study on bending properties of heterogeneous lamella layups in cross laminated timber using Australian radiata pine. Construction and Building Materials, 247, 1–14.
- Nandanwar, A., Naidu, M. V. and Pandey, C. N. (2013) Development of test methods for wooden furniture joints. Wood Material Science and Engineering, 8(3), 188–197.
- Niklewski, J. and Fredriksson, M. (2021) The effects of joints on the moisture behaviour of rain exposed wood: a numerical study with experimental validation. Wood Material Science and Engineering, 16(1), 1–11.
- Parisi, M. A. and Cordié, C. (2010) Mechanical behavior of double-step timber joints. Construction and Building Materials, 24(8), 1364–1371.
- Ren, G., Xue, J., Xu, D. and Ma, L. (2021) Experimental and theoretical analysis on rotation performance of cross-shaped joints with dowel in traditional timber structures. Journal of Building Engineering, 37, 1–13.
- Ross, P. (2002) Appraisal and Repair of Timber Structures (London: Thomas teldford Publishing).
- Saavedra, H., García-Herrera, C., Vasco, D. A. and Salinas-Lira, C. (2021) Characterization of mechanical performance of Pinus radiata wood impregnated with octadecane as phase change material. Journal of Building Engineering, 34, 1–8.
- Sandberg, D., Kutnar, A., Karlsson, O. and Jones, D. (2021) Wood Modification Technologies Principles, Sustainability, and the Need for Innovation (Boca Raton: CRC Press).
- Siem, J. (2017) The single-step joint–a traditional carpentry joint with new possibilities. International Wood Products Journal, 8, 45–49.
- Standards Australia (2010) Timber Structures Part 1 : Design Methods (Sydney: Australian Standard ®).
- Sumiyoshi, T. and Matsui, G. (1989) Wood Joints in Classical Japanese Architecture (Tokyo: Kajima Institute Publishing Co., Ltd).
- Thelandersson, S. and Larsen, H. (2003) Timber Engineering (Chichester: Wiley).
- Tuhkanen, E. and Ojamaa, M. (2021) Early experimental investigations on slotted-in steel plate connections with self-perforating dowels in CLT. Wood Material Science and Engineering, 16(2), 102–109.
- Vergara, E. (2014) En Detalle: Especial / Los ensambles de madera en la arquitectura japonesa tradicional [online]. Available from: https://www.plataformaarquitectura.cl/cl/02-369472/en-detalle-especial-los-ensambles-de-madera-en-la-arquitectura-japonesa-tradicional [Accessed 1 Sep 2021].
- Wei, J., Rao, F., Huang, Y., Zhang, Y., Qi, Y., Yu, W. and Hse, C. Y. (2019) Structure, mechanical performance, and dimensional stability of radiata pine (Pinus radiata D. Don) scrimbers. Advances in Polymer Technology, 2019, 1–8.
- Yeomans, D. (2003) The Repair of Historic Timber Structures (London: Thomas Telford).