Browsing by Author "Ningappa, A."
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Item Assessment of different long-term aging effect on FAM mixtures(CRC Press/Balkema, 2020) Ningappa, A.; Suresha, S.N.Aging is considered as one of the major factors which increase stiffness and brittleness to asphaltic mixture. This study aimed at evaluating the effect of different aging protocol on viscoelastic and fatigue cracking of Fine Aggregate Matrix (FAM) mixtures. To evaluate this, six different long-term aging levels were considered. LinearVisco-Elastic (LVE) limit of each FAMmixtures was initially determined by conducting strain sweep test.Viscoelastic properties (|G∗| and δ) and master curve shape parameters of FAMmixtures were further determined from temperature and frequency sweep test. Fatigue cracking of FAMmixtures was evaluated using G-R parameter. Irrespective of the aging level applied to the FAM specimen, LVE limit was found almost constant for all FAMmixtures.Viscoelastic properties for FAMspecimen aged for 24 hrs at 135°C, and 12 days at 95°C aged FAM mixtures showed similar results from the master curve plots. Despite of the similar viscoelastic properties, the FAM mixtures with 12 days at 95?C and 24 hrs at 135°C were not shown similar crack potential. © 2021 Taylor & Francis Group, London.Item Laboratory evaluation of long-term aging effect on linear viscoelastic and fatigue properties of FAM mixtures(2020) Ningappa, A.; Suresha, S.N.Aging is considered as one of the major factor which causes an increase in stiffness and brittleness to asphaltic mixture. This study aimed at evaluating the effect of different aging protocol on viscoelastic and fatigue properties of Fine Aggregate Matrix (FAM) which represents the finer portion (passing 2.36 mm sieve size) of asphalt concrete mixtures. To evaluate the effect of aging on viscoelastic and fatigue properties of FAM mixtures, six different long-term aging levels (6 h at 135 C, 12 h at 135 C, 24 h at 135 C, 5 days at 95 C, and 12 days at 95 C aging on FAM loose mixture and 5 days at 85 C on compacted FAM specimens) were considered. Linear Visco-Elastic (LVE) limit of each FAM mixtures was initially determined by conducting strain sweep test. Viscoelastic properties (|G*| and ?) and master curve shape parameters of FAM mixtures were further determined from temperature and frequency sweep test. Fatigue properties of FAM mixtures at different aging levels were evaluated using strain controlled time sweep test. Irrespective of the aging level applied to the FAM specimen, the LVE limit was found almost constant for all FAM mixtures. Viscoelastic properties (|G*| and ?) for FAM specimen aged for 24 h at 135 C, and 12 days at 95 C aged FAM mixtures showed similar results from the master curve plots. The fatigue properties of FAM mixtures decreased as the aging level changed from 5 days at 95 C to higher level aging of 12 days at 95 C. Despite of the similar viscoelastic properties, the trend observed between FAM mixtures aged 12 days at 95 C and 24 h at 135 C were not found to have similar fatigue properties. Findings of this study on FAM phase can be successfully used to characterize the effect of long-term aging on performance studies of FAM mixtures. 2020 Elsevier LtdItem Laboratory evaluation of long-term aging effect on linear viscoelastic and fatigue properties of FAM mixtures(Elsevier Ltd, 2020) Ningappa, A.; Suresha, S.N.Aging is considered as one of the major factor which causes an increase in stiffness and brittleness to asphaltic mixture. This study aimed at evaluating the effect of different aging protocol on viscoelastic and fatigue properties of Fine Aggregate Matrix (FAM) which represents the finer portion (passing 2.36 mm sieve size) of asphalt concrete mixtures. To evaluate the effect of aging on viscoelastic and fatigue properties of FAM mixtures, six different long-term aging levels (6 h at 135 °C, 12 h at 135 °C, 24 h at 135 °C, 5 days at 95 °C, and 12 days at 95 °C aging on FAM loose mixture and 5 days at 85 °C on compacted FAM specimens) were considered. Linear Visco-Elastic (LVE) limit of each FAM mixtures was initially determined by conducting strain sweep test. Viscoelastic properties (|G*| and ?) and master curve shape parameters of FAM mixtures were further determined from temperature and frequency sweep test. Fatigue properties of FAM mixtures at different aging levels were evaluated using strain controlled time sweep test. Irrespective of the aging level applied to the FAM specimen, the LVE limit was found almost constant for all FAM mixtures. Viscoelastic properties (|G*| and ?) for FAM specimen aged for 24 h at 135 °C, and 12 days at 95 °C aged FAM mixtures showed similar results from the master curve plots. The fatigue properties of FAM mixtures decreased as the aging level changed from 5 days at 95 °C to higher level aging of 12 days at 95 °C. Despite of the similar viscoelastic properties, the trend observed between FAM mixtures aged 12 days at 95 °C and 24 h at 135 °C were not found to have similar fatigue properties. Findings of this study on FAM phase can be successfully used to characterize the effect of long-term aging on performance studies of FAM mixtures. © 2020 Elsevier LtdItem Recent trends and laboratory performance studies on FAM mixtures: A state-of-the-art review(Elsevier Ltd, 2018) Suresha, S.N.; Ningappa, A.In recent years, the testing and evaluation of Fine Aggregate Matrix (FAM) mixtures using Dynamic Shear Rheometer (DSR) which has drawn a growing interest because of its simplicity, reproducibility, and flexibility. However, several research studies have employed various sets of test methods for performance evaluation of FAM mixtures that calls for a critical review of the procedures that have been followed to date. This state-of-the-art review article presents the current work regarding material selection, sample fabrication methods and test methods to evaluate viscoelastic, fracture and healing properties of FAM mixtures. © 2018 Elsevier Ltd