Abstract
Building elements are required to provide sufficient fire resistance based on requirements set forth in the National Building Code of Canada (NBCC). Annex B of the Canadian standard for wood engineering design (CSA O86-19) provides a design methodology to calculate the structural fire-resistance of large cross-section timber elements. However, it lacks at providing design provisions for connections. The objectives of this study are to understand the fire performance of modern mass timber fasteners such as self-tapping screws, namely to evaluate their thermo-mechanical behavior and to predict their structural fire-resistance for standard fire exposure up to two hours, as would be required for tall buildings in Canada. The results present the great fire performance of using self-tapping screws under a long time exposure on connections in mass timber construction. The smaller heated area of the exposed surface has limited thermal conduction along the fastener’s shanks and maintained their temperature profiles relatively low for two hours of exposure. Based on the heat-affected area, the study presents new design principles to determine the residual length of penetration that would provide adequate load-capacity of the fastener under fire conditions. It also allows determining safe fire-resistance values for unprotected fasteners in mass timber construction exposed up to two hours of standard fire exposure.
Highlights
Due to the urbanization and the densification of cities [1], high-rise buildings are being planned and constructed in many countries
A common practice is that connections between elements are deemed to be designed so that they provide at least the same fire-resistance as the elements they support as specified in Annex B of the Canadian standard for wood engineering design (CSA O86-19) [8]
This study presents the fire performance of using self-tapping screws used for connections in mass timber constructions
Summary
Due to the urbanization and the densification of cities [1], high-rise buildings are being planned and constructed in many countries. The most widely used time–temperature curves in standard fire tests are ASTM E119 [5], CAN/ULC S101 [6], and ISO 834 [7] Based on these test specifications [5,6,7], the fire resistance of building elements can be achieved by supporting the design load for the entire duration required of the fire test. These standard tests apply to single elements such as floors/ceilings, walls, beams, and columns. With one hour or higher of fireresistance required in tall mass timber buildings in many countries [3,9,10,11], it is essential to determine the thermomechanical behavior of timber connections for long fire exposure
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