Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Development of Corps-STIF 1.0 with Application to Ultra-High Performance Concrete (UHPC)
This report introduces the first release of CORPS-STIF (Concrete Observations Repository and Predictive Software Structural and Thermodynamical Integrated Framework). CORPS-STIF is envisioned to be used as a tool to optimize material constituents and geometries of mass concrete placements specifically for ultra-high performance concretes (UHPCs). An observations repository (OR) containing results of 649 mechanical property tests and 10 thermodynamical tests were recorded to be used as inputs for current and future releases. A thermodynamical integrated framework (TIF) was developed where the heat transfer coefficient was a function of temperature and determined at each time step. A structural integrated framework (SIF) modeled strength development in cylinders that underwent isothermal curing. CORPS-STIF represents a step toward understanding and predicting strength gain of UHPC for full-scale structures and specifically in mass concrete.
Development of Corps-STIF 1.0 with Application to Ultra-High Performance Concrete (UHPC)
This report introduces the first release of CORPS-STIF (Concrete Observations Repository and Predictive Software Structural and Thermodynamical Integrated Framework). CORPS-STIF is envisioned to be used as a tool to optimize material constituents and geometries of mass concrete placements specifically for ultra-high performance concretes (UHPCs). An observations repository (OR) containing results of 649 mechanical property tests and 10 thermodynamical tests were recorded to be used as inputs for current and future releases. A thermodynamical integrated framework (TIF) was developed where the heat transfer coefficient was a function of temperature and determined at each time step. A structural integrated framework (SIF) modeled strength development in cylinders that underwent isothermal curing. CORPS-STIF represents a step toward understanding and predicting strength gain of UHPC for full-scale structures and specifically in mass concrete.
Development of Corps-STIF 1.0 with Application to Ultra-High Performance Concrete (UHPC)
I. L. Howard (Autor:in) / T. Allard (Autor:in) / A. Carey (Autor:in) / M. Priddy (Autor:in) / A. Knizley (Autor:in) / J. D. Shannon (Autor:in)
2021
173 pages
Report
Keine Angabe
Englisch
Physics , Structural Mechanics , Construction Equipment, Materials, & Supplies , Computer Software , Construction , Construction materials , Elastic properties , Engineers , Environment , Heat transfer , Heat transfer coefficients , High performance concrete , Materials laboratories , Materials science , Materials testing , Mechanical properties , Mechanics , Modulus of elasticity , Physical properties , Three dimensional , Two dimensional
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UHPC: Ultra-High Performance Concrete
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UHPC Time-dependent behaviour of ultra high performance concrete (UHPC)
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UHPC Triaxial Fatigue Behaviour of ultra high performance concrete (UHPC)
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