International Conference on Engineering and Technology Development (ICETD)

For communities in Thailand that carries day-time dwellers of aging people, women and children especially old communities that is mostly contained of wooden houses, strength of building structure has been depended upon the ability of maintenance of people. Even wooden houses are generally seen but craftsman carpenters are not enough available and more expensive. Thought, they are easily built with basic tools and skill as cutting and hammering but, their strength is varied because they are also related to personal vitality and ability in construction and budget. Under the study framework, the relationship of personal construction ability and load carrying of structure are the main consideration to explore an appropriated method of wooden house reconstruction that is strongly enough for live load, easy for everyone to build and reduce the cost. It must promote sustainable conservation and development while it is contributing sufficiency living. So, actual load carrying has been investigated by measuring of house and furniture before calculating. An ability has been tested by target groups’ workshops. The data has been classified by types of material; reused woods and general construction woods, basic tools as hammer and nails and 2 methods of construction; cutting and joining. Two data has been compared and matched together to find the decent alternative. It seems that, the alternative material probably suitable for people’s ability but it needs more design to strengthen and makes it easy to construct

American Wood Council (AWC). (n.d.). Connection Calculator. Retrieved August 29, 2017, from

http://www.awc.org/codes-standards/calculators-software/connectioncalc

Densities of Wood Species. (n.d.). Retrieved August 31, 2017, from

http://www.engineeringtoolbox.com/wood-density-d_40.html

Engineering Institute of Thailand (EIT). 2001. Standard 1002-16 Standard of Timber Building.

Heino, E. (1985). Mearure and Construction of the Japanese House (1st ed., Vol. 1985).

Singapore: Tuttle Publishing.

Itoh, T. (2004). Architectural Development of the Japanese House and Wood Species Used.

Retrieved from http://www.nara.accu.or.jp/elearning/2004/architectural.pdf

Ochshorn,J. (2009). Wood fastener capacity calculator. Retrieved August 29, 2017, from

https://courses.cit.cornell.edu/arch264/calculators/example9.1/

Office of council of state. Building Standard Act 1979 5th edition 2017, Pub. L. No. Book 134,

section 18A, The Government Gazette, 2017.

Poomchalit, W, K. Suzuki, and A. Suzuki. (2017). “The Relationship Between the Spatial

Developments and the Change of Wooden-Houses in Original Settlements in the Expansion

Suburban Area of Bangkok.” presented at the 2017 Workshop on Urban Planning and

Management, Sophia University, Tokyo, February 18.

Schweitzer, R. (2004). Traditional Japanese wood construction. Presented at the Internationales

Holzbau-Forum 2004.

Tucker, B. J., Pollock, D., Fridley, K. J., & Peters, J. J. (2000). Governing Yield Modes for

Common Bolted and Nailed Wood Connections. Department of Mechanical and Civil

Engineering, George Fox University, United State.

Yamato,S. (2006). The Tradition of Wooden Architecture in Japan. Retrieved from

http://www.nara.accu.or.jp/elearning/2006/tradition.pdf