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Analytical Study of the Effect of Full and Partial Masonry Infills on the Seismic Performance of School Buildings

조적채움벽 및 허리벽이 학교 건물 내진 성능에 미치는 영향에 대한 해석적 연구

  • Kim, Tae Wan (Department of Architectural Engineering, Kangwon National University) ;
  • Min, Chan Gi (Korea Infrastructure Safety Corporation)
  • Received : 2013.05.23
  • Accepted : 2013.06.28
  • Published : 2013.09.02

Abstract

The seismic performance of school buildings has been a matter of common interest socially and academically. The structural system of the school buildings is representative of the domestic low-rise reinforced concrete moment resisting frames, which apply extensively infills in their masonry walls. The masonry infilled walls are divided into full masonry infill in the transverse direction and partial masonry infill in the longitudinal direction. The masonry infilled walls are usually not included in structural analysis during the design process, but affect significantly the seismic performance because they behave with surrounding frames simultaneously during earthquakes. Many researchers have studied the effect of the masonry infilled walls, but several issues have been missed such as the increase of asymmetry by adding the full masonry infill, the size of the mean strength of the full masonry infill, and short column effect by the partial masonry infill. The issues were analytically investigated and the results showed that they should be checked at least by nonlinear pushover analysis in the seismic performance evaluation process. The results also confirm the weakness of the guideline of Korean Educational Development Institute where the seismic performance is basically assessed without structural analysis.

Keywords

References

  1. KEDI. Guidelines for seismic performance evaluation and rehabilitation of school buildings. Seoul, Korea: Korean Educational Development Institute; c2011. 112p.
  2. KISC. Guidelines for seismic performance evaluation and rehabilitation of existing buildings. Kyeonggi-do, Korea: Korea Infrastructure Safety Corporation; c2004. 224p.
  3. KISC. Guidelines for seismic performance evaluation and rehabilitation of existing buildings. Kyeonggi-do, Korea: Korea Infrastructure Safety Corporation; c2011. 115p.
  4. NEMA. Guidelines for seismic performance evaluation of buildings. Seoul, Korea: National Emergency Management Agency; c2012. 150p.
  5. ASCE41. Seismic rehabilitation of existing buildings. Reston, VA: American Society of Civil Engineers; c2006. 411p.
  6. JBDPA, Standard and commentary for seismic evaluation of existing reinforced concrete buildings. Tokyo, Japan: Japan Building Disaster Prevention Association; c2001.
  7. Shin JH, Kim HS. An experimental study on the bearing force and efficiency of masonry infilled frame. Journal of the Architectural Institute of Korea. 1989 Feb; 5(1): 173-182.
  8. Chang CH, Kim YM. Behavior of non-seismic detailed low-rise reinforced concrete frame by cyclic loading. Journal of the Regional Association of Architectural Institute of Korea. 2002 Apr;4(4): 127-133.
  9. Lee JH, Cha SL, Kang DE, Oh SH, Lee YJ, Yi WH, Kim SD. An experimental study on seismic capacity evaluation of brick infilled RC frame. Proceedings of the Architectural Institute of Korea conference. 2004 Apr;24(1):39-42.
  10. Cho WS, Lee SH, Chung L, Kim HJ, Kim SJ, Yu EJ. Seismic performance evaluation of reinforced concrete frame with unreinforced masonry infill. Journal of the Architectural Institute of Korea. 2012 Mar;28(3):31-41.
  11. Kim KT, Seo SY, Yoon SJ, Yoshimura K. Experimental study for seismic performance of confined brick masonry wall system. Proceedings of the Architectural Institute of Korea conference. 2004 Oct; 24(2):195-198.
  12. Choi H. Cyclic loading test of reinforced concrete frame with unreinforced concrete block infill. Journal of the Architectural Institute of Korea. 2007 Apr;23(4):71-78.
  13. Hwang SR, Kim JS, Yoon TH. The inelastic behavior of the existing buildings considering infilled masonry walls. Journal of the Regional Association of Architectural Institute of Korea. 2008 Dec;10(4):191-198.
  14. Park JH, Jeon SH, Kang KS. Seismic performance evaluation of masonry-infilled frame structures using equivalent strut models. Journal of the Earthquake Engineering Society of Korea. 2012 Feb;16(1):47-59. https://doi.org/10.5000/EESK.2012.16.1.047
  15. ATC40. Seismic evaluation and retrofit of concrete building. Redwood city, CA: Applied Technology Council; c1996.
  16. FEMA440. Improvement of nonlinear static seismic analysis procedures. Washington, D.C.: Federal Emergency Management Agency; c2005.
  17. MIDAS GEN User's Manual. ver 785. MIDAS IT; c2010.
  18. KBC2009. Korean building code-structural. Seoul, Korea: Architectural Institute of Korea; c2009. 772p.

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