Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Shear resistance performance evaluations of rubber asphalt waterproof adhesive layer on bridge deck
Shear resistance performance between asphalt concrete surfacing and cement concrete is very important to guarantee the service life of deck paving. Insufficient shear resistance will result in some premature damage, such as cutting-slippage, folding, spalling, and loose. Shear resistance performance of rubber asphalt waterproof-adhesive layer was evaluated with oblique shear experiment under common design high-low temperature condition (20¢C, 50¢C and -10¢C). With the different effect of loading rate and rubber asphalt spraying quality, shear resistance performance was evaluated with indexes such as maximum shear stress (τmax), shear resistance energy (Et) and ultimate shear deformation (δb). Results show that shear resistance performance of rubber asphalt waterproof adhesive layer under three different temperature conditions are significantly different. Under high temperature: τmax and Et decrease significantly when temperature varies from 20¢C to 50¢C; meanwhile the two indexes are affected by rubber asphalt spraying quality insignificantly; the fundamental factor determining shear resistance ability is interaction ability between rubber asphalt and concrete surface. Under -10¢C: Rubber asphalt waterproof-adhesive layer shows elastic properties; the relationship between shear stress and shear deformation shows general linear; δb decreases significantly, but shear stress is great enough to improve Et to an increased result. So, the spraying quality and shear resistance ability can be determined and evaluated by the three indexes (τmax, Et, δb) tested by oblique shear experiment.
Shear resistance performance evaluations of rubber asphalt waterproof adhesive layer on bridge deck
Shear resistance performance between asphalt concrete surfacing and cement concrete is very important to guarantee the service life of deck paving. Insufficient shear resistance will result in some premature damage, such as cutting-slippage, folding, spalling, and loose. Shear resistance performance of rubber asphalt waterproof-adhesive layer was evaluated with oblique shear experiment under common design high-low temperature condition (20¢C, 50¢C and -10¢C). With the different effect of loading rate and rubber asphalt spraying quality, shear resistance performance was evaluated with indexes such as maximum shear stress (τmax), shear resistance energy (Et) and ultimate shear deformation (δb). Results show that shear resistance performance of rubber asphalt waterproof adhesive layer under three different temperature conditions are significantly different. Under high temperature: τmax and Et decrease significantly when temperature varies from 20¢C to 50¢C; meanwhile the two indexes are affected by rubber asphalt spraying quality insignificantly; the fundamental factor determining shear resistance ability is interaction ability between rubber asphalt and concrete surface. Under -10¢C: Rubber asphalt waterproof-adhesive layer shows elastic properties; the relationship between shear stress and shear deformation shows general linear; δb decreases significantly, but shear stress is great enough to improve Et to an increased result. So, the spraying quality and shear resistance ability can be determined and evaluated by the three indexes (τmax, Et, δb) tested by oblique shear experiment.
Shear resistance performance evaluations of rubber asphalt waterproof adhesive layer on bridge deck
Ji, Lun (Autor:in) / Li, Yunliang (Autor:in) / Wang, Haipeng (Autor:in) / Zhang, Lei (Autor:in) / Tan, Yiqiu (Autor:in)
International Symposium of Climatic Effects on Pavement and Geotechnical Infrastructure 2013 ; 2013 ; Fairbanks, Alaska
02.04.2014
Aufsatz (Konferenz)
Elektronische Ressource
Englisch
The Connection Properties of Rubber Asphalt Waterproofing Adhesive Layer in Bridge Deck Pavement
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