A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
High-strain rate tension behavior of Fiber-Reinforced Rubberized Concrete
https://orcid.org/0000-0002-9364-5160
Abstract This paper investigates for the first time the high-strain rate splitting tension behavior of Fiber-Reinforced Rubberized Concrete (FRRC). Splitting tension tests were performed on 100-mm specimens. Quasi-static tests were carried out using conventional quasi-static loading with a compressive testing machine and dynamic high-strain rate tests with a 80-mm Split Hopkinson Pressure Bar (SHPB) for strain rates up to . The experimental program comprises the characterization of Plain Concrete (PC), Fiber Reinforced Concrete (FRC), Rubberized Concrete (RuC), and FRRC with a full test matrix (a total of 240 specimens) covering fiber contents up to 1.5% and rubber volume substitution ratios up to 30%. A high-speed camera was used to capture the cracking development processes together with Digital Image Correlation (DIC). The addition of fibers enhances the deformation capacity with a marked increase in the tensile strength both for quasi-static and dynamic conditions while the substitution with rubber aggregates significantly reduces the tensile strength with a similar enhancement of the deformation capacity. For FRRC, a combination of the two effects was observed. FRC, RuC, and FRRC are characterized by marked strain rate dependency within the considered test range. Furthermore, data-driven models for compression and tension strength reduction factor ( and ) and tension Dynamic Increase Factor () are proposed for different types of FRRC. Finally, a discussion on the image-based damage development processes is provided based on the high-speed camera videos. This study indicates that FRRC has an excellent high-strain rate tension behavior reducing and controlling the crack propagation.
Highlights We tested Fiber-Reinforced Rubberized Concrete (FRRC) with different fiber and rubber contents. Tension tests were conducted covering strain rates between quasi-static to . Damage development was investigated by means of DIC technique. We proposed a data-driven model for the strength reduction factor and Dynamic Increase Factor. Image-based fracture development processes is discussed.
High-strain rate tension behavior of Fiber-Reinforced Rubberized Concrete
https://orcid.org/0000-0002-9364-5160
Abstract This paper investigates for the first time the high-strain rate splitting tension behavior of Fiber-Reinforced Rubberized Concrete (FRRC). Splitting tension tests were performed on 100-mm specimens. Quasi-static tests were carried out using conventional quasi-static loading with a compressive testing machine and dynamic high-strain rate tests with a 80-mm Split Hopkinson Pressure Bar (SHPB) for strain rates up to . The experimental program comprises the characterization of Plain Concrete (PC), Fiber Reinforced Concrete (FRC), Rubberized Concrete (RuC), and FRRC with a full test matrix (a total of 240 specimens) covering fiber contents up to 1.5% and rubber volume substitution ratios up to 30%. A high-speed camera was used to capture the cracking development processes together with Digital Image Correlation (DIC). The addition of fibers enhances the deformation capacity with a marked increase in the tensile strength both for quasi-static and dynamic conditions while the substitution with rubber aggregates significantly reduces the tensile strength with a similar enhancement of the deformation capacity. For FRRC, a combination of the two effects was observed. FRC, RuC, and FRRC are characterized by marked strain rate dependency within the considered test range. Furthermore, data-driven models for compression and tension strength reduction factor ( and ) and tension Dynamic Increase Factor () are proposed for different types of FRRC. Finally, a discussion on the image-based damage development processes is provided based on the high-speed camera videos. This study indicates that FRRC has an excellent high-strain rate tension behavior reducing and controlling the crack propagation.
Highlights We tested Fiber-Reinforced Rubberized Concrete (FRRC) with different fiber and rubber contents. Tension tests were conducted covering strain rates between quasi-static to . Damage development was investigated by means of DIC technique. We proposed a data-driven model for the strength reduction factor and Dynamic Increase Factor. Image-based fracture development processes is discussed.
High-strain rate tension behavior of Fiber-Reinforced Rubberized Concrete
https://orcid.org/0000-0002-9364-5160
Abstract This paper investigates for the first time the high-strain rate splitting tension behavior of Fiber-Reinforced Rubberized Concrete (FRRC). Splitting tension tests were performed on 100-mm specimens. Quasi-static tests were carried out using conventional quasi-static loading with a compressive testing machine and dynamic high-strain rate tests with a 80-mm Split Hopkinson Pressure Bar (SHPB) for strain rates up to . The experimental program comprises the characterization of Plain Concrete (PC), Fiber Reinforced Concrete (FRC), Rubberized Concrete (RuC), and FRRC with a full test matrix (a total of 240 specimens) covering fiber contents up to 1.5% and rubber volume substitution ratios up to 30%. A high-speed camera was used to capture the cracking development processes together with Digital Image Correlation (DIC). The addition of fibers enhances the deformation capacity with a marked increase in the tensile strength both for quasi-static and dynamic conditions while the substitution with rubber aggregates significantly reduces the tensile strength with a similar enhancement of the deformation capacity. For FRRC, a combination of the two effects was observed. FRC, RuC, and FRRC are characterized by marked strain rate dependency within the considered test range. Furthermore, data-driven models for compression and tension strength reduction factor ( and ) and tension Dynamic Increase Factor () are proposed for different types of FRRC. Finally, a discussion on the image-based damage development processes is provided based on the high-speed camera videos. This study indicates that FRRC has an excellent high-strain rate tension behavior reducing and controlling the crack propagation.
Highlights We tested Fiber-Reinforced Rubberized Concrete (FRRC) with different fiber and rubber contents. Tension tests were conducted covering strain rates between quasi-static to . Damage development was investigated by means of DIC technique. We proposed a data-driven model for the strength reduction factor and Dynamic Increase Factor. Image-based fracture development processes is discussed.
High-strain rate tension behavior of Fiber-Reinforced Rubberized Concrete
Lai, Dade (author) / Demartino, Cristoforo (author) / Xiao, Yan (author)
2022-04-17
Article (Journal)
Electronic Resource
English
Flexural Behavior of Steel Fiber-Reinforced Rubberized Concrete
| British Library Online Contents | 2016