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Field Measurement of Vertical Movement and Roof Moisture Performance of the Wood Innovation and Design Centre

https://research.thinkwood.com/en/permalink/catalogue1638
Year of Publication
2016
Topic
Moisture
Serviceability
Material
CLT (Cross-Laminated Timber)
Glulam (Glue-Laminated Timber)
PSL (Parallel Strand Lumber)
Application
Roofs
Wood Building Systems
Author
Wang, Jieying
Karsh, Eric
Finch, Graham
Chen, Mingyuk
Year of Publication
2016
Country of Publication
Austria
Format
Conference Paper
Material
CLT (Cross-Laminated Timber)
Glulam (Glue-Laminated Timber)
PSL (Parallel Strand Lumber)
Application
Roofs
Wood Building Systems
Topic
Moisture
Serviceability
Keywords
Moisture Content
Vertical Movement
Temperature
Relative Humidity
Monitoring
Language
English
Conference
World Conference on Timber Engineering
Research Status
Complete
Notes
August 22-25, 2016, Vienna, Austria p. 3152-3160
Summary
The Wood Innovation and Design Centre (WIDC) in Prince George, British Columbia, with 6 tall storeys and a total height of 29.5 m, provided a unique opportunity for non-destructive testing and monitoring to measure the ‘As Built’ performance of a relatively tall mass timber building. The mass timber structural system consists of glulam columns and beams with cross laminated timber (CLT) floor plates and shear walls. Vertical movement of selected glulam columns and CLT walls and the moisture content of the innovative mass timber roof were monitored as these components are unique to mass timber buildings. Indoor temperature and relative humidity conditions were also measured. The mass timber CLT and glulam elements are susceptible to longer-term differential movement as they slowly dry after manufacturing and construction. The paper describes instrumentation and discusses the measurement results for two years following the topping out of the structure. The monitoring indicated that the wood inside the building could reach a moisture content (MC) close to 4% in the winter in this cold climate, from an initial MC of around 13% during construction. Glulam columns were dimensionally stable in the longitudinal direction given the MC changes and loading conditions. With a height of over 5 m and 6 m, respectively, two glulam columns directly measured by sensors each showed vertical movement below 3 mm (i.e., 0.04%). The cumulative shortening of the six glulam columns along the height of the columns (24.5 m) is expected to be approximately 11 mm. This did not take into consideration any potential settlement or deformation at connections between glulam columns, or effects of reduced loads on the top two unoccupied floors. The CLT wall panels were also dimensionally stable along the height of the building, with cumulative vertical shrinkage of about 19 mm (i.e., 0.07%) from Level 1 to Level 6. In contrast, the 5-ply CLT floor slabs made up of wood in radial and tangential grain shrank in thickness by about 5 mm (3.0%) on average. With regards to the performance of the mass timber roof, the CLT roof panels started out dry and remained dry due to the robust assembly design and the dry indoor conditions. In one area the plywood roof sheathing was initially wetted by the application of a concrete topping below a piece of mechanical equipment, it was able to dry to the interior within a few months. Overall the monitoring study showed that the differential movement occurring among the glulam columns and the CLT wall was small and the mass timber roof design had good drying performance.
Online Access
Free
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Pres-Lam in the US: The Seismic Design of the Peavy Building at Oregon State University

https://research.thinkwood.com/en/permalink/catalogue1475
Year of Publication
2017
Topic
Design and Systems
Mechanical Properties
Seismic
Material
CLT (Cross-Laminated Timber)
Glulam (Glue-Laminated Timber)
Timber-Concrete Composite
Application
Hybrid Building Systems
Author
Sarti, Francesco
Smith, Tobias
Danzig, Ilana
Karsh, Eric
Year of Publication
2017
Country of Publication
New Zealand
Format
Conference Paper
Material
CLT (Cross-Laminated Timber)
Glulam (Glue-Laminated Timber)
Timber-Concrete Composite
Application
Hybrid Building Systems
Topic
Design and Systems
Mechanical Properties
Seismic
Keywords
Pres-Lam
Load Carrying Capacity
US
Codes
Nonlinear Time History Analysis
Language
English
Conference
New Zealand Society for Earthquake Engineering Conference
Research Status
Complete
Notes
April 27-29, 2017, Wellington, New Zealand
Summary
Pres-Lam is a post-tensioned rocking timber technology that has been developed over the last decade at the University of Canterbury. Pres-Lam overcomes a major challenge in timber construction, the development of a high strength moment connection, by tying mass timber elements together with high-strength steel post-tensioned tendons. In seismic areas, additional reinforcing can be added to the system increasing capacity as well as providing hysteretic damping. In 2010 Pres-Lam moved from laboratory testing to onsite implementation and has now been used in the construction of numerous building in New Zealand and around the world. This paper will present the lateral load design of the first Pres-Lam structure to be built in the United States: the Peavy Building at Oregon State University, Corvallis, Oregon. Peavy is a three-storey mass timber building within the College of Forestry. A glulam and CLT gravity structure support the timber-concrete-composite floor, which is made up of CLT panels spanning between glulam beams. The lateral load carrying capacity is provided in the two orthogonal directions by Pres-Lam walls fabricated from Cross Laminated Timber (CLT). The paper will present an overview of the design philosophy and the main motivations for the use of the Pres-Lam system, discuss the requirements for U.S. code compliance, and review the nonlinear time-history analysis of the Pres-Lam structure.
Online Access
Free
Resource Link
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