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Author: Burak F. Tanyu Publisher: ISBN: Category : Pavements, Asphalt concrete Languages : en Pages : 0
Book Description
This report is written to summarize the findings of a study conducted by George Mason University's (GMU) Sustainable Geo Infrastructure (SGI) Research group to evaluate the expansion of using reclaimed asphalt pavement (RAP) and to optimize the RAP content in unbound base aggregate. The particular scope of the research presented in this report has been determined by the VTRC/VDOT team and included a laboratory and a field study. Prior to the initiation of the research, based on the conversations with Virginia's road building industry it was determined that the research will focus on evaluating what is referred as "fine processed" RAP (100% of the particles finer than 1-inch). Virgin aggregate (VA) used in this study complied with the VDOT's 21A gradation and contained geologically similar aggregate pieces (diabase). During the initial phase, based on the availability, samples of RAP from 14 different asphalt plants in Virginia were collected and characterized. The goal was to assess the similarities and differences between the RAP produced throughout the Commonwealth. The results showed that all RAP samples had similar grain size distribution and primarily contained pieces of aggregate that were of diabase origin. The binder (asphalt) content of the samples ranged from 4.4 to 6.1%. Based on this characterization, samples from three different plants that represented a low, medium, and high binder content RAP were selected for detailed evaluation. The ages of the collected RAP samples were not known and most likely varied. Laboratory evaluation focused on assessing the performance of the RAP-VA blends against the performance of the 100% VA alone. CBR, resilient modulus (Mr), and permanent deformation (PD) tests were used to evaluate performance. Up to 60% RAP (with three different binder contents) was blended with VA by weight. Results from PD tests showed a threshold where some addition of RAP into VA improved the performance but beyond a specific threshold, the overall performance started to decline. This threshold was determined to be a function of both the percentage of RAP added to a blend and the percentage of the binder content of the 100% RAP used. The optimized maximum RAP percentage in a given blend was determined in this study as up to 20% for RAP with low binder content (i.e., d"4.6%) and up 30% for RAP with high binder content (i.e., e"5.6 %). The reasons why RAP with different binder content resulted in different percent threshold requires further investigation as it could be due to the differences in the age of the RAP, which was not part of the scope of this study. Field evaluation part of the study involved in constructing an actual roadway with four different base course layers consisting of 20 and 30% RAP-VA blends with low (4.5%) and high (5.7%) binder contents. Sections constructed with VA alone were used as a comparison (control sections). Field study demonstrated that Light Weight Deflectometer and modified speedy moisture content tests are suitable tools to be used for quality control of RAP-VA blends during construction. Performance evaluation in the field was monitored for a year with the embedded instruments and nondestructive tests conducted during and after the construction. Results obtained from the field were in agreement with the laboratory observations. Based on the findings from laboratory and supported by the field observations, a relationship between the binder content of the 100% RAP and maximum allowed RAP percentage to create RAP-VA blends is created to provide guidelines for implementation
Author: Burak F. Tanyu Publisher: ISBN: Category : Pavements, Asphalt concrete Languages : en Pages : 0
Book Description
This report is written to summarize the findings of a study conducted by George Mason University's (GMU) Sustainable Geo Infrastructure (SGI) Research group to evaluate the expansion of using reclaimed asphalt pavement (RAP) and to optimize the RAP content in unbound base aggregate. The particular scope of the research presented in this report has been determined by the VTRC/VDOT team and included a laboratory and a field study. Prior to the initiation of the research, based on the conversations with Virginia's road building industry it was determined that the research will focus on evaluating what is referred as "fine processed" RAP (100% of the particles finer than 1-inch). Virgin aggregate (VA) used in this study complied with the VDOT's 21A gradation and contained geologically similar aggregate pieces (diabase). During the initial phase, based on the availability, samples of RAP from 14 different asphalt plants in Virginia were collected and characterized. The goal was to assess the similarities and differences between the RAP produced throughout the Commonwealth. The results showed that all RAP samples had similar grain size distribution and primarily contained pieces of aggregate that were of diabase origin. The binder (asphalt) content of the samples ranged from 4.4 to 6.1%. Based on this characterization, samples from three different plants that represented a low, medium, and high binder content RAP were selected for detailed evaluation. The ages of the collected RAP samples were not known and most likely varied. Laboratory evaluation focused on assessing the performance of the RAP-VA blends against the performance of the 100% VA alone. CBR, resilient modulus (Mr), and permanent deformation (PD) tests were used to evaluate performance. Up to 60% RAP (with three different binder contents) was blended with VA by weight. Results from PD tests showed a threshold where some addition of RAP into VA improved the performance but beyond a specific threshold, the overall performance started to decline. This threshold was determined to be a function of both the percentage of RAP added to a blend and the percentage of the binder content of the 100% RAP used. The optimized maximum RAP percentage in a given blend was determined in this study as up to 20% for RAP with low binder content (i.e., d"4.6%) and up 30% for RAP with high binder content (i.e., e"5.6 %). The reasons why RAP with different binder content resulted in different percent threshold requires further investigation as it could be due to the differences in the age of the RAP, which was not part of the scope of this study. Field evaluation part of the study involved in constructing an actual roadway with four different base course layers consisting of 20 and 30% RAP-VA blends with low (4.5%) and high (5.7%) binder contents. Sections constructed with VA alone were used as a comparison (control sections). Field study demonstrated that Light Weight Deflectometer and modified speedy moisture content tests are suitable tools to be used for quality control of RAP-VA blends during construction. Performance evaluation in the field was monitored for a year with the embedded instruments and nondestructive tests conducted during and after the construction. Results obtained from the field were in agreement with the laboratory observations. Based on the findings from laboratory and supported by the field observations, a relationship between the binder content of the 100% RAP and maximum allowed RAP percentage to create RAP-VA blends is created to provide guidelines for implementation
Author: Randy Clark West Publisher: Transportation Research Board ISBN: 0309259134 Category : Pavements, Asphalt Languages : en Pages : 162
Book Description
TRB's National Cooperative Highway Research Program (NCHRP) Report 752: Improved Mix Design, Evaluation, and Materials Management Practices for Hot Mix Asphalt with High Reclaimed Asphalt Pavement Content describes proposed revisions to the American Association of State Highway and Transportation Officials (AASHTO) R 35, Superpave Volumetric Design for Hot Mix Asphalt, and AASHTO M 323, Superpave Volumetric Mix Design, to accommodate the design of asphalt mixtures with high reclaimed asphalt pavement contents.
Author: Munir D. Nazzal Publisher: ISBN: Category : Binders (Materials) Languages : en Pages :
Book Description
This report summarizes the research work that was completed to assess the optimum percentages of recycled asphalt pavement (RAP) that can be used in surface course mixtures of local roadways while ensuring durability is maintained. This project was divided into two phases. Phase 1 included conducting a comprehensive laboratory testing on mixtures with different RAP contents and recycling agents. Based on the results of Phase 1, Phase 2 of this project involved constructing eight test sections as a part of a resurfacing project on Hall Road in the City of Columbus. Surface course asphalt mixtures with a similar aggregate blend but different percentages of RAP were used in these test sections. The first section (control section) had a mix with 20% RAP and PG 64-22 binder. While three test sections had mixes with 30%, 40%, 50% RAP, PG 64-22 binder, and Sylvaroad recycling agent, three other sections had mixes with the same RAP percentages and binder but used Hydrolene as the recycling agent. Finally, the last section was constructed using a mixture containing 30% RAP and PG 64-28 binder with no recycling agent. Cores were obtained at different locations within each test section. In addition, specimens were compacted in a laboratory from loose mixtures that were obtained during the construction of each test section. Tests were done on field cores and laboratory-compacted specimens. The test results showed that Hydrolene was more effective than Sylvaroad in improving the fatigue cracking resistance of RAP mixes with more than 0.3 binder. In addition, the tests results showed that the 30% RAP, 40% RAP, and 50% RAP mixes had similar low-temperature cracking resistance to that of the control. The laboratory test results also showed that all mixes had acceptable rutting resistance. The results of the cost analyses conducted in Phase 2 indicated that using a higher RAP content of 40% and recycling agents can reduce the initial cost of an asphalt mixture by at least 15%.
Author: Publisher: ISBN: Category : Pavements, Asphalt Languages : en Pages : 561
Book Description
The objective of this study was to improve Reclaimed Asphalt Pavement (RAP) strength in base course applications while reducing creep to an acceptable level using compaction techniques, fractionating, blending with high quality base course aggregate, and/or by chemical stabilization with asphalt emulsion, Portland cement, or lime. RAP/limerock blends with and without chemical stabilization were compacted by modified Proctor, Marshall, or gyratory methods, cured, and tested for strength and creep. Strength tests included limerock bearing ratio (LBR), unconfined compression, Marshall compression, and indirect tensile tests. Strength specimens were tested dry and soaked to evaluate retained strength. Seven-day one-dimensional creep testing was performed. Gyratory compaction produced higher densities than modified Proctor or Marshall compaction. At the same density, gyratory compaction improved RAP strength by a factor of two to three over modified Proctor but had less effect on creep. Modified Proctor moisture-density plots followed an S-shape without a clear optimum; modified Proctor may not be the best method to predict RAP compaction behavior. Fractionating RAP did not improve strength or creep unless RAP was remixed to match a maximum density curve. Fractionating did not produce acceptable LBRs or creep. RAP blended with limerock, cemented coquina, or reclaimed concrete aggregates showed improved LBR and creep performance. RAP/aggregate blends have the potential to be used as Florida base course. As the amount of aggregate blended with RAP increased, LBR increased and creep decreased. Creep behavior of blends with 75 percent aggregate was similar to 100 percent aggregate. Unstabilized blends with 50 percent aggregate did not produce LBR values over 100. Blends of 50 percent RAP/50 percent limerock stabilized with 1 percent of either asphalt emulsion or cement attained soaked LBRs over 100 and acceptable creep. Blends of RAP with 75 percent limerock attained soaked LBRs close to 100 and low creep without any chemical stabilizer. Adding RAP to limerock blends generally increased the soaked retained strength and improved permeability compared to 100 percent limerock.
Author: Albert Marshall Bleakley Publisher: ISBN: Category : Languages : en Pages : 668
Book Description
Reclaimed Asphalt Pavement (RAP) is produced by milling during resurfacing operations. Finding innovative ways to incorporate RAP into highway base course applications will provide both environmental and economic benefits by allowing in situ recycling of material for projects such as widening or shoulder addition. RAP is a well-drained granular material which is already on site, however 100% RAP is low bearing strength and creeps under load. The objective of this research was to develop methods to improve RAP's strength while reducing creep to an acceptable level through blending with high quality crushed limestone aggregate and/or by chemical stabilization with asphalt emulsion, Portland cement, or lime. RAP/aggregate blends with and without chemical stabilization were compacted by modified Proctor, Marshall, or gyratory methods, cured, and tested for strength and creep. Strength tests included limerock bearing ratio (LBR), a variant of the CBR test, unconfined compression, Marshall compression, and indirect tensile tests. Strength specimens were tested dry and soaked to evaluate retained strength. One dimensional creep testing was performed using seven day oedometer tests. RAP/aggregate blends have the potential to be used successfully as a base course material. Blends of RAP with 50% limerock base material attained a soaked LBR strength of 100 and acceptable levels of creep with the addition of 1% of either asphalt emulsion or cement. Blends of RAP with 75% or more limerock attained a soaked LBR close to 100 and low levels of creep without any chemical stabilizer. In general adding RAP to limerock blends increased the soaked retained strength and improved permeability compared to 100% limerock. Gyratory compaction achieved higher densities than modified Proctor or Marshall compaction and improved RAP's strength by a factor of two to three compared to modified Proctor compaction at the same density but had less effect on creep. Field testing is required to determine whether it is feasible to reproduce the gyratory compaction results on an actual construction site. Significant variability was noted between results with different blends, compaction methods, and stabilizing agents. Site specific performance testing should be conducted to establish the viability of blending RAP into a base or subbase.
Author: Imad L. Al-Qadi Publisher: ISBN: Category : Pavements, Asphalt Languages : en Pages : 32
Book Description
Illinois has been recycling Reclaimed Asphalt Pavement (RAP) material into hot-mix asphalt (HMA) since 1980, this research project seeks to determine the appropriate level of contribution that should be given to the residual asphalt binder in RAP.
Author: Burak F. Tanyu
Author: Burak F. Tanyu
Author: Frank Palise
Author: Randy Clark West
Author: Rebecca McDaniel
Author: Mengqi Wu
Author: Munir D. Nazzal
Author: 
Author: Lamar Caylor
Author: Albert Marshall Bleakley
Author: Imad L. Al-Qadi