Structural Performance of Typical Beam-Column Joints in Yingxian Wood Pagoda - An Experimental Study

Zhi Yong Chen; En Chun Zhu; Jing Long Pan; Guo Fang Wu

doi:10.4028/www.scientific.net/KEM.517.669

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 517Structural Performance of Typical Beam-Column...

Structural Performance of Typical Beam-Column Joints in Yingxian Wood Pagoda - An Experimental Study

Abstract:

Yingxian Wood Pagoda, built in 1056, is located in the town of Yingxian County, Shanxi Province, China. It is the oldest and highest standing ancient wood structure in China. The pagoda is octagon-shaped in plan, with a total height of 67.31m and a base diameter of 30.27m. It appears as a five-storeyed structure, but actually consists of nine storeys, with four shorter but stiffer storeys hidden between the five apparent storeys. Yingxian Wood Pagoda was built without any metal connectors like nail, screw, or bolt. Instead, Tenon-Mortise connections and Dou-Gong brackets were used to connect all posts and beams. Tenon-Mortise connections and Dou-Gong brackets have been playing a vital role for the pagoda to resist severe winds, earthquakes and some human-induced disasters for nearly a thousand years. To evaluate the safety of the pagoda, it is, therefore, useful to investigate the structural performance of the beam-column joints, most important for Yingxian Wood Pagoda to resist lateral load. In this study, two models of typical beam-column joints of the pagoda, MBCJ-I and MBCJ-II, were manufactured following a ratio of 3.4 to the prototype of the joints. Non-destructive cyclic loading test of the models under different vertical load and destructive cyclic test of the models under vertical load of 20kN were conducted. The hysteretic stiffness of MBCJ-I was lager than MBCJ-II, and increased linearly with vertical load N. The relationship between and N was obtained by regression of the test results using the least square method. The stiffness of model joint under vertical load was 70.6kN/mm. The failure modes, energy-dissipation performance, moment resistance and bending stiffness of both model joints were derived and discussed.

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Periodical:

Key Engineering Materials (Volume 517)

Pages:

669-676

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.517.669

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Online since:

June 2012

Authors:

Zhi Yong Chen, En Chun Zhu, Jing Long Pan, Guo Fang Wu

Keywords:

Ancient Wood Structure, Beam-Column Joint, Tenon-Mortise Connection, Yingxian Wood Pagoda

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References

[1] M.D. Chen, Yingxian Wood Pagoda. Cultural Relic Press, Beijing, (2001).

Google Scholar

[2] E.C. Zhu, Z.Y. Chen and J.L. Pan, Finite Element Modelling of Dou-Gong Brackets of Yingxian Wood Pagoda, in: 11th World Conference on Timber Engineering (WCTE 2010), Trentino, (2010).

Google Scholar

[3] J. Li, Ying Zao Fa Shi. China Bookstore Press, Beijing, (2006).

Google Scholar

[4] State Forestry Bureau of the People's Republic of China, Method of Testing in Compressive Strength Parallel to Grain of Wood GB/T 1935-2009, Standards Press of China, Beijing, (2009).

Google Scholar

[5] State Forestry Bureau of the People's Republic of China, Method of Testing in Shearing Strength Parallel to Grain of Wood GB/T 1937-2009, Standards Press of China, Beijing, (2009).

Google Scholar

[6] State Forestry Bureau of the People's Republic of China, Method of Testing in Tensile Strength Parallel to Grain of Wood GB/T 1938-2009, Standards Press of China, Beijing, (2009).

Google Scholar

[7] State Forestry Bureau of the People's Republic of China, Method of Testing in Compression Perpendicular to Grain of Wood GB/T 1939-2009, Standards Press of China, Beijing, (2009).

Google Scholar

[8] State Forestry Bureau of the People's Republic of China, Method for Determination of the Modulus of Elasticity in Compression Parallel to Grain of Wood GB/T 15777-1995, Standards Press of China, Beijing, (1995).

Google Scholar

[9] State Forestry Bureau of the People's Republic of China, Method for Determination of the Modulus of Elasticity in Compression Perpendicular to Grain of Wood GB/T 1943-2009, Standards Press of China, Beijing, (2009).

Google Scholar

[10] State Forestry Bureau of the People's Republic of China, Method of Testing in Tensile Strength Perpendicular to Grain of Wood GB/T 14017-2009, Standards Press of China, Beijing, (2009).

Google Scholar

[11] American Society for Testing and Materials, Standard Test methods for Small Clear Specimens of Timber D143-94, ASTM, West Conshohocken, (2007).

Google Scholar

[12] L.Y. Wang, Z.Y. Lu, S.J. Shen, Study on Twelve Elastic Constant Values of Betula Platyphylla Suk Wood, Journal of Beijing Forestry University. Vol. 25, No. 6 (2003) 64-67.

Google Scholar

[13] Minstry of Construction of the People's Republic of China. Specificating of Testing Methods for Earthquake Resistant Building JGJ 101-96, China Architecture and Building Press, (1996).

Google Scholar