Correlating Laboratory and Field Compaction Levels to Achieve Optimum In Situ Mechanical Properties for Pervious Concrete Pavements

AbstractMechanical properties of pervious concrete (PC) are highly influenced by the applied compaction; however, the required level of compaction to achieve the desired density and strength in the field is currently unknown. In some cases, compaction is established empirically on costly test panels...

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Veröffentlicht in:	Journal of materials in civil engineering 2020-10, Vol.32 (10), Article 04020278
Hauptverfasser:	AlShareedah, Othman, Haider, Md Mostofa, Nassiri, Somayeh
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Sprache:	eng
Schlagworte:	Building materials Civil engineering Compressive strength Concrete pavements Construction & Building Technology Engineering Engineering, Civil Laboratories Levels Materials Science Materials Science, Multidisciplinary Mechanical properties Porosity Science & Technology Technical Papers Technology
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description	AbstractMechanical properties of pervious concrete (PC) are highly influenced by the applied compaction; however, the required level of compaction to achieve the desired density and strength in the field is currently unknown. In some cases, compaction is established empirically on costly test panels. In this study, the relationship between the applied compaction force and the hardened porosity (Ø) and compressive strength (fc) was investigated. Three PC mix proportions with varying paste contents were compacted in the laboratory using a lightweight deflectometer (LWD) at four different compaction levels. Porosity and 7-day fc testing were carried out on cylinders cast with each compaction level. In general, the first 15 LWD drops influenced Ø and fc significantly, while the effect of compaction beyond that level was less significant. The applied compaction force recorded by the LWD was used to obtain the required properties of a rotary roller-screed to apply an equivalent compaction force in the field. Then, regression-based models were developed to estimate the 7-day Ø and fc of PC based on the applied compaction force and the paste content. The developed models provide a practical solution to compute the required compaction force in the field to achieve the desired PC mechanical properties.
doi_str_mv	10.1061/(ASCE)MT.1943-5533.0003361
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In some cases, compaction is established empirically on costly test panels. In this study, the relationship between the applied compaction force and the hardened porosity (Ø) and compressive strength (fc) was investigated. Three PC mix proportions with varying paste contents were compacted in the laboratory using a lightweight deflectometer (LWD) at four different compaction levels. Porosity and 7-day fc testing were carried out on cylinders cast with each compaction level. In general, the first 15 LWD drops influenced Ø and fc significantly, while the effect of compaction beyond that level was less significant. The applied compaction force recorded by the LWD was used to obtain the required properties of a rotary roller-screed to apply an equivalent compaction force in the field. Then, regression-based models were developed to estimate the 7-day Ø and fc of PC based on the applied compaction force and the paste content. 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In some cases, compaction is established empirically on costly test panels. In this study, the relationship between the applied compaction force and the hardened porosity (Ø) and compressive strength (fc) was investigated. Three PC mix proportions with varying paste contents were compacted in the laboratory using a lightweight deflectometer (LWD) at four different compaction levels. Porosity and 7-day fc testing were carried out on cylinders cast with each compaction level. In general, the first 15 LWD drops influenced Ø and fc significantly, while the effect of compaction beyond that level was less significant. The applied compaction force recorded by the LWD was used to obtain the required properties of a rotary roller-screed to apply an equivalent compaction force in the field. Then, regression-based models were developed to estimate the 7-day Ø and fc of PC based on the applied compaction force and the paste content. 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subjects	Building materials Civil engineering Compressive strength Concrete pavements Construction & Building Technology Engineering Engineering, Civil Laboratories Levels Materials Science Materials Science, Multidisciplinary Mechanical properties Porosity Science & Technology Technical Papers Technology
title	Correlating Laboratory and Field Compaction Levels to Achieve Optimum In Situ Mechanical Properties for Pervious Concrete Pavements
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