In-Plane Monotonic and Cyclic Racking Load Testing of Structural Insulated Panels
Publication: Journal of Architectural Engineering
Volume 18, Issue 4
Abstract
Structural insulated panel (SIP) wall systems have been used in residential and light commercial buildings for the past 60 years. Lack of sufficient published research results on racking load performance and understanding of the influence of fastener types on seismic response has been a deterrent in the widespread use of the wall system in seismically active areas. This paper summarizes the results of a full-scale racking load testing study in which a total of SIP wall panels were tested under monotonic and cyclic loading. Four 114-mm (4.5-in.) thick SIP specimens were tested under monotonic loading, while 13 114-mm (4.5-in.) thick SIP specimens were tested under the Consortium of Universities for Research in Earthquake Engineering loading protocol. Parameters such as fastener type, spline design, hold-down anchor location, and sheathing bearing were adjusted throughout the testing to determine their effects on the SIP’s performance. Performance parameters such as peak load and displacement and allowable drift load capacity were determined for all of the SIP specimens. The paper describes the mode of failure for typical specimens under both monotonic and cyclic loading and presents load-displacement data for the tested specimens. The study showed that the fastener type (screw, staple, or nail) was the parameter that had the greatest effect on the performance of the specimen. The SIP specimens that used 8d common nails to connect the framing to the sheathing are shown to be the most effective SIP design in terms of load capacity and resistance under repeated cyclic loading.
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Acknowledgments
This research presented in this report was made possible through partial support of SIPA. The SIPs for testing were donated by Timberline Panel Company. These contributions are gratefully acknowledged. In development of the research program and throughout the study the researchers benefitted from suggestions and comments by several individuals including Bill Wachtler, Jim DeStefano, Scott Maxwell, Jim Whalen, Borjen Yeh, Todd Bergstrom, Eric Tompos, Joe Hagerman, and Joe Pasma. For the experimental study the help of the following students is acknowledged: Dan Clark, Dan Navarrete, Joe Ridgeway, and Hiroki Ota. In particular, the invaluable help of BERL Laboratory Supervisor, Paul Kremer, in all aspects of the experimental work including test setup design, data acquisition system design, and data analysis is acknowledged. The views and opinions expressed in this report are those of the authors and do not necessarily represent SIPA’s position.
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© 2012 American Society of Civil Engineers.
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Received: Jan 6, 2010
Accepted: Dec 28, 2011
Published online: Nov 15, 2012
Published in print: Dec 1, 2012
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