The document discusses the use of recycled asphalt pavement (RAP) in stone matrix asphalt mixes, with RAP replacements of 10%, 30%, and 50% tested. Laboratory tests such as the Marshall test and indirect tensile strength test were conducted on specimens to evaluate the performance of mixes with different RAP contents. The results of the tests were analyzed to determine the optimum RAP percentage for stone matrix asphalt based on strength and economic considerations.
This document provides information on flexible pavement design and theory. It discusses the typical layers of a flexible pavement including the surface course, base course, and subgrade. It also outlines several factors that affect pavement design such as wheel load, climate, and material characteristics. Additionally, the document examines failures like fatigue cracking and rutting that pavement design aims to prevent. It provides guidance on mechanistic-empirical design as prescribed by the Indian Roads Congress.
The document discusses different methods for recycling pavements, including flexible and rigid pavements. For flexible pavements, it describes in-place hot and cold recycling processes as well as hot and cold central plant recycling. For rigid pavements, it discusses breaking, crushing and processing concrete to produce recycled concrete aggregate (RCA), which can be used in new concrete. It notes that recycling provides benefits like reduced costs, preservation of resources and the environment.
This document discusses the design and construction of flexible pavements. It begins by outlining the purpose of pavements to carry traffic smoothly and safely while distributing loads. It then describes the main types of pavements as flexible (uses bitumen) and rigid (uses concrete). The bulk of the document details the layers of flexible pavements, potential failures, testing of aggregates, types of bitumen, and the construction process. It concludes by covering geometric standards for flexible pavements such as camber, carriageway, and shoulders.
The document discusses different types of pavements. It describes flexible pavements as having multiple layers that distribute loads through aggregate interlock. Rigid pavements distribute loads through the beam strength of concrete slabs. Flexible pavements are composed of surface, base, and sub-base layers over a subgrade, while rigid pavements typically only require a concrete surface layer. Both pavement types are designed to reduce loads from vehicles to prevent damage to the subgrade. The document compares advantages and disadvantages of flexible and rigid pavements.
Design Considerations for AASHTO Flexible pavement designImran Nawaz
The document discusses the key factors considered in AASHTO flexible pavement design: pavement performance, traffic, roadbed soils, materials of construction, environment, drainage, and reliability. Pavement performance is measured by present serviceability index (PSI) on a scale of 0 to 5. Traffic is considered in terms of estimated single axle loads (ESALs). Roadbed soils are characterized by properties like CBR, R-value, and resilient modulus (Mr). Materials are assigned structural numbers (SN) based on properties. Drainage and environment affect Mr. Reliability ensures the design survives the design life with a given level of probability. The design process involves determining layer SNs from properties then thickness to achieve a
The document describes the different layers of a flexible pavement, including the surface course, binder course, base course, subbase course, and subgrade. The surface course is the top layer and provides skid resistance, with a thickness of 25-50mm. The binder course is below this and is constructed of aggregates and bitumen. The base course distributes loads and is a minimum of 100mm thick. Below this is the subbase course, which provides drainage and a base for the base course. The bottom layer is the subgrade, which is the compacted natural soil acting as the pavement foundation.
This document discusses the construction of flexible pavements. It begins by introducing the types and components of flexible and rigid pavements. The key components of flexible pavement include the subgrade, sub-base course, base course, binder course, and surface course. It then describes the construction process for each layer, including preparing and compacting the subgrade, placing and compacting the granular sub-base and base courses, applying prime coats and tack coats, and paving the asphalt binder and surface courses. In comparison, rigid pavements are constructed as a solid slab that distributes loads differently than the layered system of flexible pavements.
Project presentation on flexible pavement by Harshit Prakash Gargharshit315
The document provides details on the design of a 750 meter flexible pavement in India. It includes soil tests, layer designs, thickness calculations using CBR and traffic values, and a cost estimate. A drum mix plant overview is also included to mix asphalt for pavement construction. Key steps are conducting CBR, sieve analysis and density tests; designing layers per IRC codes; determining 635mm thickness from charts; and estimating a total cost of 13.06 lakhs rupees.
This document provides information on flexible pavement design and theory. It discusses the typical layers of a flexible pavement including the surface course, base course, and subgrade. It also outlines several factors that affect pavement design such as wheel load, climate, and material characteristics. Additionally, the document examines failures like fatigue cracking and rutting that pavement design aims to prevent. It provides guidance on mechanistic-empirical design as prescribed by the Indian Roads Congress.
The document discusses different methods for recycling pavements, including flexible and rigid pavements. For flexible pavements, it describes in-place hot and cold recycling processes as well as hot and cold central plant recycling. For rigid pavements, it discusses breaking, crushing and processing concrete to produce recycled concrete aggregate (RCA), which can be used in new concrete. It notes that recycling provides benefits like reduced costs, preservation of resources and the environment.
This document discusses the design and construction of flexible pavements. It begins by outlining the purpose of pavements to carry traffic smoothly and safely while distributing loads. It then describes the main types of pavements as flexible (uses bitumen) and rigid (uses concrete). The bulk of the document details the layers of flexible pavements, potential failures, testing of aggregates, types of bitumen, and the construction process. It concludes by covering geometric standards for flexible pavements such as camber, carriageway, and shoulders.
The document discusses different types of pavements. It describes flexible pavements as having multiple layers that distribute loads through aggregate interlock. Rigid pavements distribute loads through the beam strength of concrete slabs. Flexible pavements are composed of surface, base, and sub-base layers over a subgrade, while rigid pavements typically only require a concrete surface layer. Both pavement types are designed to reduce loads from vehicles to prevent damage to the subgrade. The document compares advantages and disadvantages of flexible and rigid pavements.
Design Considerations for AASHTO Flexible pavement designImran Nawaz
The document discusses the key factors considered in AASHTO flexible pavement design: pavement performance, traffic, roadbed soils, materials of construction, environment, drainage, and reliability. Pavement performance is measured by present serviceability index (PSI) on a scale of 0 to 5. Traffic is considered in terms of estimated single axle loads (ESALs). Roadbed soils are characterized by properties like CBR, R-value, and resilient modulus (Mr). Materials are assigned structural numbers (SN) based on properties. Drainage and environment affect Mr. Reliability ensures the design survives the design life with a given level of probability. The design process involves determining layer SNs from properties then thickness to achieve a
The document describes the different layers of a flexible pavement, including the surface course, binder course, base course, subbase course, and subgrade. The surface course is the top layer and provides skid resistance, with a thickness of 25-50mm. The binder course is below this and is constructed of aggregates and bitumen. The base course distributes loads and is a minimum of 100mm thick. Below this is the subbase course, which provides drainage and a base for the base course. The bottom layer is the subgrade, which is the compacted natural soil acting as the pavement foundation.
This document discusses the construction of flexible pavements. It begins by introducing the types and components of flexible and rigid pavements. The key components of flexible pavement include the subgrade, sub-base course, base course, binder course, and surface course. It then describes the construction process for each layer, including preparing and compacting the subgrade, placing and compacting the granular sub-base and base courses, applying prime coats and tack coats, and paving the asphalt binder and surface courses. In comparison, rigid pavements are constructed as a solid slab that distributes loads differently than the layered system of flexible pavements.
Project presentation on flexible pavement by Harshit Prakash Gargharshit315
The document provides details on the design of a 750 meter flexible pavement in India. It includes soil tests, layer designs, thickness calculations using CBR and traffic values, and a cost estimate. A drum mix plant overview is also included to mix asphalt for pavement construction. Key steps are conducting CBR, sieve analysis and density tests; designing layers per IRC codes; determining 635mm thickness from charts; and estimating a total cost of 13.06 lakhs rupees.
This document discusses the classification and testing of highway materials. It begins by classifying highway materials into minerals, common building materials, and binding materials. It then focuses on subgrade soil, describing its uses in highways and desirable properties. The California Bearing Ratio test is described for determining the strength and stability of subgrade soil. Stone aggregates are also classified and their desirable properties discussed. Common tests for stone aggregates are described, including the Los Angeles Abrasion test, Aggregate Impact test, and tests for specific gravity and water absorption.
A highway is any public or private road or other public way on land. It is used for major roads, but also includes other public roads and public tracks: It is not an equivalent term to controlled-access highway, or a translation for autobahn, autoroute, etc.
In North American and Australian English, major roads such as controlled-access highways or arterial roads are often state highways (Canada: provincial highways). Other roads may be designated "county highways" in the US and Ontario. These classifications refer to the level of government (state, provincial, county) that maintains the roadway.
In British English, "highway" is primarily a legal term. Everyday use normally implies roads, while the legal use covers any route or path with a public right of access, including footpaths etc.
The term has led to several related derived terms, including highway system, highway code, highway patrol and highwayman.
The term highway exists in distinction to "waterway".
This document summarizes a study on the design of flexible pavements. It includes an abstract that outlines a comparison of total present costs between flexible pavement and jointed plain concrete pavement for two case study roads. The document then lists contents that will be covered, including introduction to flexible pavements and their layers/functions, different flexible pavement design approaches, testing and materials used, construction processes, and a conclusion. It provides an overview of flexible pavement requirements, types, load transfer mechanisms, and common flexible pavement constructions.
SUBGRADE SOIL STRENGTH AND ITS EVALUTION Sagar Kaptan
This document discusses subgrade soil strength and its evaluation. It explains that soil strength depends on factors like soil type, moisture content, dry density, and stress application. It then describes Coulomb's equation for shear strength as being equal to apparent cohesion plus the normal stress times the tangent of the friction angle. Common tests to evaluate soil strength are then outlined as bearing tests, shear tests, and penetration tests. Specific tests mentioned include the plate load test, direct shear test, triaxial compression test, unconfined compression test, vane shear test, California bearing ratio test, and cone penetration tests.
perpetual pavement is one of the new technology in the construction field of roads in these we discussed about how to construct, and what is the step by step process to be followed and advantages and dis advantages of perpetual pavements ,case study also we discussed
The Marshall stability and flow test provides the performance prediction measure for the Marshall mix design method. The stability portion of the test measures the maximum load supported by the test specimen at a loading rate of 50.8 mm/minute. Load is applied to the specimen till failure, and the maximum load is designated as stability. During the loading, an attached dial gauge measures the specimen's plastic flow (deformation) due to the loading. The flow value is recorded in 0.25 mm (0.01 inch) increments at the same time when the maximum load is recorded.
Introduction of Pavement Design
Functions of the Pavement
Requirement of Pavement
Types of Pavement
Component of Flexible Pavement
Load Distribution
types of failure
Design mix method of bitumenous materials by Marshall stability methodAmardeep Singh
4.25
4.5
4.75
5
5.25
5.5
Bitumen %
1) The Marshall stability test is used to determine the optimum asphalt content for a given mix design by evaluating stability, flow, density, voids, and voids filled with asphalt at different asphalt contents.
2) Specimens are compacted in molds and tested at 60°C after being submerged in a water bath for 30-40 minutes.
3) Graphs of stability, density, and voids vs. asphalt content are used to identify the optimum asphalt content, which
Rigid pavements are constructed using reinforced concrete slabs that provide a strong wearing surface and base course. They are used in areas with adverse conditions like heavy rainfall, poor soil/drainage, or extreme climate. Materials for rigid pavements include Portland cement, coarse and fine aggregates, and water. Reinforcement includes dowel bars at joints. Rigid pavements have longitudinal and transverse joints, including contraction joints to relieve stresses, expansion joints to allow for expansion, and construction joints. They can be constructed using slipform pavers, fixed form pavers, or manual methods. Quality control checks materials and finished surface properties. Traffic is allowed after a minimum 28-day curing period.
This document discusses failures in flexible pavement. It begins by defining the different types of highway pavement, including flexible, rigid, and other pavements like semi-rigid or composite. It then lists 10 common types of failures in flexible pavement such as alligator cracking, rutting, shear failure cracking, and pumping. The document concludes by explaining the causes of these failures, with causes including repeated heavy loads, moisture variations in layers, lack of bonding between layers, and movement across cracks.
Plastic as a soil stabilizer by yashwanth sagaryashwanth9611
This document summarizes a study on using plastic as a soil stabilizer. Standard Proctor compaction tests were conducted on lateritic soil mixed with varying percentages of cut plastic strips. California Bearing Ratio (CBR) tests found that adding 0.4% plastic strips improved the 4-day soaked CBR value of the soil. Plate load tests also showed increased shear strength and load capacity with the addition of plastic. The results indicate that using plastic waste can enhance soil properties for road construction and provide an effective way to reuse non-degradable waste.
The document discusses the different layers of flexible pavement, including the granular sub-base, granular base course, and bituminous layers. It describes the materials, construction processes, and quality control tests for each layer. Specifically, it outlines the objectives and materials used for the granular sub-base layer, including crushed stone aggregates, gravel, coarse sand, and requirements for material passing sieves. It also discusses the compaction and testing requirements for constructing the granular sub-base layer.
The document describes the Marshall method of determining the optimum binder content for a bituminous mix design. Aggregates and binder are heated and mixed to different binder contents. Specimens are compacted with blows from a hammer and tested for properties like flow value, stability, and density. Graphs are made plotting these properties against the varying binder contents. The optimum binder content is determined as the percentage where the graphs show highest stability and density and lowest flow value.
This document provides information on dense bituminous macadam (DBM), which is a binder course used for road construction. It discusses the design criteria, materials, job mix formula, and construction process for DBM layers. DBM mixes are designed in the laboratory to meet specific stability and durability requirements. The design considers factors like aggregate type and gradation, binder content, and compaction parameters. DBM layers are constructed by preparing the base, mixing the materials, spreading the mix, compacting it with rollers, and then opening the road to traffic once cooled.
Stone columns are a versatile ground improvement technique used since the 1950s. They involve compacting coarse aggregate in columns in the ground to reinforce, densify and drain weak soils. Stone columns can improve bearing capacity, stability, reduce settlements and mitigate liquefaction. They work by transferring loads around them to stiffer columns, accelerating consolidation. Installation methods include ramming and vibro-replacement. Case studies show stone column embankments experience less settlement than untreated ground. In summary, stone columns are an effective ground improvement technique to strengthen weak soils.
This document describes the California Bearing Ratio (CBR) test, which is used to determine the strength of soils and granular materials for pavement design. The CBR test involves compacting a soil sample and measuring the penetration of a piston under increasing loads. The CBR value is the load required to penetrate the sample 2.5mm or 5mm divided by a standard load value. Higher CBR values indicate stronger soils suitable for supporting pavement layers. The document outlines the apparatus, test procedure, interpretation of results, and classification of subgrade strength based on CBR values.
introduction to soil stabilization and introduction to geo textiles and synth...husna004
This document provides definitions and information about soil stabilization techniques. It discusses mechanical and additive stabilization, including the uses of stabilization to improve soil quality and reduce pavement thickness. Key additive stabilization methods described are portland cement, lime, fly ash, and bitumen. The document provides guidance on selecting additive stabilizers based on soil type and properties. It also discusses considerations for using stabilized soils in frost areas and determining the appropriate stabilizer content.
The document discusses various tests conducted on bitumen, including penetration tests to determine hardness, ductility tests to measure adhesion and ability to stretch, viscosity tests to measure resistance to flow, softening point tests using a ring and ball to determine temperature susceptibility, and flash and fire point tests to identify ignition temperatures. In total, nine different tests are outlined that examine key properties of bitumen like hardness, adhesion, flow resistance, temperature performance, and ignition points.
A highway pavement is a structure consisting of superimposed layers of processed materials above the natural soil sub-grade, whose primary function is to distribute the applied vehicle loads to the sub-grade. The pavement structure should be able to provide a surface of acceptable riding quality, adequate skid resistance, favorable light reflecting characteristics, and low noise pollution.
The document discusses various types of soils used in subgrade for road construction. It describes desirable properties of subgrade soil including stability, drainage, and ease of compaction. It also discusses different soil types commonly used in India and their classification. Various laboratory tests conducted on soil are outlined including shear tests, bearing tests, and penetration tests like the California Bearing Ratio test. The test procedures for CBR and plate bearing tests are summarized.
The document provides information on bitumen mixes used for road construction. It discusses the constituents of bitumen mixes, which include aggregates, filler, and binders like bitumen. It describes different types of mixes like dense graded, stone matrix, and open graded mixes. It also covers characteristics of materials used in mixes and production methods for both hot and cold bitumen mixes. Cold mixes use bitumen emulsions and avoid heating of aggregates and binders.
Barry McKeon presented on full depth reclamation (FDR) at an APWA conference. FDR is an economical recycling technique that uniformly pulverizes and stabilizes the full flexible pavement section and a portion of the underlying base with an emulsion or foamed asphalt. The presentation covered the FDR process, advantages like using 100% existing materials and increased load bearing strength, equipment overview, project applications, quality control, and environmental and economic benefits. FDR results in a more moisture tolerant base course that can resist cracking and widening projects.
This document discusses the classification and testing of highway materials. It begins by classifying highway materials into minerals, common building materials, and binding materials. It then focuses on subgrade soil, describing its uses in highways and desirable properties. The California Bearing Ratio test is described for determining the strength and stability of subgrade soil. Stone aggregates are also classified and their desirable properties discussed. Common tests for stone aggregates are described, including the Los Angeles Abrasion test, Aggregate Impact test, and tests for specific gravity and water absorption.
A highway is any public or private road or other public way on land. It is used for major roads, but also includes other public roads and public tracks: It is not an equivalent term to controlled-access highway, or a translation for autobahn, autoroute, etc.
In North American and Australian English, major roads such as controlled-access highways or arterial roads are often state highways (Canada: provincial highways). Other roads may be designated "county highways" in the US and Ontario. These classifications refer to the level of government (state, provincial, county) that maintains the roadway.
In British English, "highway" is primarily a legal term. Everyday use normally implies roads, while the legal use covers any route or path with a public right of access, including footpaths etc.
The term has led to several related derived terms, including highway system, highway code, highway patrol and highwayman.
The term highway exists in distinction to "waterway".
This document summarizes a study on the design of flexible pavements. It includes an abstract that outlines a comparison of total present costs between flexible pavement and jointed plain concrete pavement for two case study roads. The document then lists contents that will be covered, including introduction to flexible pavements and their layers/functions, different flexible pavement design approaches, testing and materials used, construction processes, and a conclusion. It provides an overview of flexible pavement requirements, types, load transfer mechanisms, and common flexible pavement constructions.
SUBGRADE SOIL STRENGTH AND ITS EVALUTION Sagar Kaptan
This document discusses subgrade soil strength and its evaluation. It explains that soil strength depends on factors like soil type, moisture content, dry density, and stress application. It then describes Coulomb's equation for shear strength as being equal to apparent cohesion plus the normal stress times the tangent of the friction angle. Common tests to evaluate soil strength are then outlined as bearing tests, shear tests, and penetration tests. Specific tests mentioned include the plate load test, direct shear test, triaxial compression test, unconfined compression test, vane shear test, California bearing ratio test, and cone penetration tests.
perpetual pavement is one of the new technology in the construction field of roads in these we discussed about how to construct, and what is the step by step process to be followed and advantages and dis advantages of perpetual pavements ,case study also we discussed
The Marshall stability and flow test provides the performance prediction measure for the Marshall mix design method. The stability portion of the test measures the maximum load supported by the test specimen at a loading rate of 50.8 mm/minute. Load is applied to the specimen till failure, and the maximum load is designated as stability. During the loading, an attached dial gauge measures the specimen's plastic flow (deformation) due to the loading. The flow value is recorded in 0.25 mm (0.01 inch) increments at the same time when the maximum load is recorded.
Introduction of Pavement Design
Functions of the Pavement
Requirement of Pavement
Types of Pavement
Component of Flexible Pavement
Load Distribution
types of failure
Design mix method of bitumenous materials by Marshall stability methodAmardeep Singh
4.25
4.5
4.75
5
5.25
5.5
Bitumen %
1) The Marshall stability test is used to determine the optimum asphalt content for a given mix design by evaluating stability, flow, density, voids, and voids filled with asphalt at different asphalt contents.
2) Specimens are compacted in molds and tested at 60°C after being submerged in a water bath for 30-40 minutes.
3) Graphs of stability, density, and voids vs. asphalt content are used to identify the optimum asphalt content, which
Rigid pavements are constructed using reinforced concrete slabs that provide a strong wearing surface and base course. They are used in areas with adverse conditions like heavy rainfall, poor soil/drainage, or extreme climate. Materials for rigid pavements include Portland cement, coarse and fine aggregates, and water. Reinforcement includes dowel bars at joints. Rigid pavements have longitudinal and transverse joints, including contraction joints to relieve stresses, expansion joints to allow for expansion, and construction joints. They can be constructed using slipform pavers, fixed form pavers, or manual methods. Quality control checks materials and finished surface properties. Traffic is allowed after a minimum 28-day curing period.
This document discusses failures in flexible pavement. It begins by defining the different types of highway pavement, including flexible, rigid, and other pavements like semi-rigid or composite. It then lists 10 common types of failures in flexible pavement such as alligator cracking, rutting, shear failure cracking, and pumping. The document concludes by explaining the causes of these failures, with causes including repeated heavy loads, moisture variations in layers, lack of bonding between layers, and movement across cracks.
Plastic as a soil stabilizer by yashwanth sagaryashwanth9611
This document summarizes a study on using plastic as a soil stabilizer. Standard Proctor compaction tests were conducted on lateritic soil mixed with varying percentages of cut plastic strips. California Bearing Ratio (CBR) tests found that adding 0.4% plastic strips improved the 4-day soaked CBR value of the soil. Plate load tests also showed increased shear strength and load capacity with the addition of plastic. The results indicate that using plastic waste can enhance soil properties for road construction and provide an effective way to reuse non-degradable waste.
The document discusses the different layers of flexible pavement, including the granular sub-base, granular base course, and bituminous layers. It describes the materials, construction processes, and quality control tests for each layer. Specifically, it outlines the objectives and materials used for the granular sub-base layer, including crushed stone aggregates, gravel, coarse sand, and requirements for material passing sieves. It also discusses the compaction and testing requirements for constructing the granular sub-base layer.
The document describes the Marshall method of determining the optimum binder content for a bituminous mix design. Aggregates and binder are heated and mixed to different binder contents. Specimens are compacted with blows from a hammer and tested for properties like flow value, stability, and density. Graphs are made plotting these properties against the varying binder contents. The optimum binder content is determined as the percentage where the graphs show highest stability and density and lowest flow value.
This document provides information on dense bituminous macadam (DBM), which is a binder course used for road construction. It discusses the design criteria, materials, job mix formula, and construction process for DBM layers. DBM mixes are designed in the laboratory to meet specific stability and durability requirements. The design considers factors like aggregate type and gradation, binder content, and compaction parameters. DBM layers are constructed by preparing the base, mixing the materials, spreading the mix, compacting it with rollers, and then opening the road to traffic once cooled.
Stone columns are a versatile ground improvement technique used since the 1950s. They involve compacting coarse aggregate in columns in the ground to reinforce, densify and drain weak soils. Stone columns can improve bearing capacity, stability, reduce settlements and mitigate liquefaction. They work by transferring loads around them to stiffer columns, accelerating consolidation. Installation methods include ramming and vibro-replacement. Case studies show stone column embankments experience less settlement than untreated ground. In summary, stone columns are an effective ground improvement technique to strengthen weak soils.
This document describes the California Bearing Ratio (CBR) test, which is used to determine the strength of soils and granular materials for pavement design. The CBR test involves compacting a soil sample and measuring the penetration of a piston under increasing loads. The CBR value is the load required to penetrate the sample 2.5mm or 5mm divided by a standard load value. Higher CBR values indicate stronger soils suitable for supporting pavement layers. The document outlines the apparatus, test procedure, interpretation of results, and classification of subgrade strength based on CBR values.
introduction to soil stabilization and introduction to geo textiles and synth...husna004
This document provides definitions and information about soil stabilization techniques. It discusses mechanical and additive stabilization, including the uses of stabilization to improve soil quality and reduce pavement thickness. Key additive stabilization methods described are portland cement, lime, fly ash, and bitumen. The document provides guidance on selecting additive stabilizers based on soil type and properties. It also discusses considerations for using stabilized soils in frost areas and determining the appropriate stabilizer content.
The document discusses various tests conducted on bitumen, including penetration tests to determine hardness, ductility tests to measure adhesion and ability to stretch, viscosity tests to measure resistance to flow, softening point tests using a ring and ball to determine temperature susceptibility, and flash and fire point tests to identify ignition temperatures. In total, nine different tests are outlined that examine key properties of bitumen like hardness, adhesion, flow resistance, temperature performance, and ignition points.
A highway pavement is a structure consisting of superimposed layers of processed materials above the natural soil sub-grade, whose primary function is to distribute the applied vehicle loads to the sub-grade. The pavement structure should be able to provide a surface of acceptable riding quality, adequate skid resistance, favorable light reflecting characteristics, and low noise pollution.
The document discusses various types of soils used in subgrade for road construction. It describes desirable properties of subgrade soil including stability, drainage, and ease of compaction. It also discusses different soil types commonly used in India and their classification. Various laboratory tests conducted on soil are outlined including shear tests, bearing tests, and penetration tests like the California Bearing Ratio test. The test procedures for CBR and plate bearing tests are summarized.
The document provides information on bitumen mixes used for road construction. It discusses the constituents of bitumen mixes, which include aggregates, filler, and binders like bitumen. It describes different types of mixes like dense graded, stone matrix, and open graded mixes. It also covers characteristics of materials used in mixes and production methods for both hot and cold bitumen mixes. Cold mixes use bitumen emulsions and avoid heating of aggregates and binders.
Barry McKeon presented on full depth reclamation (FDR) at an APWA conference. FDR is an economical recycling technique that uniformly pulverizes and stabilizes the full flexible pavement section and a portion of the underlying base with an emulsion or foamed asphalt. The presentation covered the FDR process, advantages like using 100% existing materials and increased load bearing strength, equipment overview, project applications, quality control, and environmental and economic benefits. FDR results in a more moisture tolerant base course that can resist cracking and widening projects.
Bitumin mixes for road report documentationkumawat123
This document provides an introduction and overview of bituminous mix design for highway construction. It discusses the objectives of bituminous mix design which are to produce a mix that is strong, durable, resistant to fatigue and deformation, environmentally friendly, and economical. The key constituents of a bituminous mix are described as coarse aggregates, fine aggregates, filler, and binder. Different types of mixes are also outlined, including dense-graded mixes and stone matrix asphalt. The document examines requirements for bituminous mixes such as stability, durability, flexibility, and workability. Foamed asphalt is defined and the evolution of mix design methods over time is reviewed.
This document provides a summary of different types of bituminous pavement constructions and methods. It describes 12 types of constructions including interface treatment, bituminous surface dressing, seal coat, penetration macadam, built-up spray grout, bituminous macadam, bituminous premixed carpet, bituminous concrete, sheet asphalt, and mastic asphalt. It also discusses two methods of construction - hot-mix and cold-mix methods. The document serves as a guide for understanding the various techniques used for bituminous pavement projects.
This document discusses different types of modified bituminous materials used in pavement construction including polymer modified bitumen, bitumen rubber mixes, stone matrix asphalt, and warm mix asphalt. It provides details on the composition and properties of these materials. Polymer modified bitumen involves adding polymers like SBS or EVA to bitumen to improve its high temperature stability and resistance to deformation. Stone matrix asphalt contains a high percentage of coarse aggregate that forms an interlocking skeleton structure, filled with bitumen and filler, to provide durability and resist permanent deformation on heavily trafficked roads.
This document provides an overview of stone mastic asphalt (SMA), including its history, composition, advantages, disadvantages, and applications. SMA was developed in Germany in the 1960s to provide maximum resistance to rutting from studded tires. It has a high stone content of at least 70% that forms an interlocking skeleton structure filled with stiff bituminous mastic. SMA exhibits high resistance to rutting and wear, and increases pavement life by 20-30% over conventional pavements, making it suitable for heavily trafficked roads. However, it also has higher material and construction costs than other asphalt mixes.
A sample lab report on Marshall method of mix design for bituminous mixtures with all calculations.
Please request with your mail ID if you want to download this document.
Introduction to Steel Fiber Reinforced Concrete (SFRC)Zubayer Ibna Zahid
Steel fiber reinforced concrete (SFRC) contains short, closely spaced steel fibers added to concrete to improve its tensile strength. The fibers are typically 0.2-2 inches long and have a variety of possible cross-sectional shapes, such as flat, deformed, hooked, or crimped. SFRC mixes typically contain 0.2-1.0% fiber volume fraction, with higher percentages for larger aggregate sizes. The steel fibers improve the ductility and toughness of the concrete to reduce cracking and increase its post-cracking residual strength capacity.
The document discusses utilizing waste plastic in bituminous mixes for road construction. It notes that waste plastics are abundant and can be mixed with bitumen to improve its binding properties. Studies show mixing shredded plastic bags into bitumen at 20% increases compression and bending strength. Bangalore has successfully used this method on over 600 km of roads, with roads containing plastic showing less rutting and cracks. The plastic is mixed with aggregates and bitumen in a plant and laid as normal. This method provides an alternative use for plastic waste and improves road quality.
The document discusses the experimental method for research. It describes experimental method as using research designs, statistical significance testing, and quality criteria. Key aspects covered include identifying independent and dependent variables, threats to internal validity like history, maturation, testing, instrumentation, and threats to external validity like interaction of testing and treatment, reactive arrangements, and population validity. It also outlines different research designs used in experiments like one-shot case study, one-group pre-test post-test, intact groups, nonequivalent groups, time series, equivalent time samples, post-test only control group, and pre-test post-test control designs.
ppt on high performance concrete (steel fibre)9597639444
1) Steel fiber reinforced concrete has higher strength and durability than conventional concrete due to the inclusion of short, randomly distributed steel fibers.
2) Testing showed that concrete cubes with 5% steel fibers by weight had a 13.55% increase in compressive strength over conventional concrete.
3) Columns made with 5% steel fibers could carry over 14% more load than conventional concrete columns before failure. The addition of steel fibers improves several properties of concrete including flexural strength, impact resistance, and fatigue resistance.
Pineapple fiber properties and uses by vignesh dhanabalanVignesh Dhanabalan
This document summarizes research on the properties and uses of pineapple fibre. It discusses the chemical composition of the fibre, which is mostly cellulose, hemicellulose, and lignin. It describes how the fibre is extracted from pineapple leaves through retting and degumming processes to remove non-fibrous materials. The fibre has potential for use as a textile or composite material due to its physical properties. However, its spinnability and weavability could be improved by adjusting the length-to-width ratio and treating it with acids.
Recycle material used in road constructionpavan bathani
As the world population grows, so do the amount and type of waste being generated.Many of the waste produced today will remain in environment.The creation of non decaying waste material, combined with a growing consumer population, has resulted in a waste disposal crisis.
One solution to this crisis lies in recycling waste into useful products.
It is try to match society need for safe and economic disposal of waste material with highway industry need for better and more cost effective construction material.
This document is a summer internship project report submitted by Shubham Paliwal to the Department of Civil Engineering. It provides introductions and definitions related to bitumen and bituminous roads. It describes the different layers of a bituminous road, including the subgrade, sub-base, base, and wearing surface layers. It also discusses operations used in bituminous roads like seal coats, tack coats, and prime coats. References used in the project are listed at the end.
The document discusses different types of polymer matrix composites, including thermoset and thermoplastic matrices. It covers various processing techniques for composites such as hand layup, filament winding, and injection molding. Key topics include the properties and applications of polymer composites as well as the effects of temperature on thermoplastic polymers.
This document summarizes the construction of a 6.5 km private road located in Ranipur, Haridwar, India. It describes the various layers that make up the roadway, including earthwork, granular sub-base, wet mix macadam, bituminous macadam, bituminous concrete, and finishing touches like kerbs and shoulders. The layers are constructed in sequential order, with careful compaction and mixing of aggregates and binders at each stage to support vehicular traffic on the carriageway. Proper camber is built into the road surface to allow for water drainage off the sides of the paved area.
The document discusses the Marshall mix design method for determining the optimum bitumen content for an asphalt mix. The Marshall stability and flow test is used to predict mix performance. Specimens are prepared with varying bitumen contents and tested for properties like stability, flow, air voids, specific gravities. Graphs of these properties against bitumen content are used to find the optimum content as the average of the contents for maximum stability, maximum density, and 4% air voids. Calculations of mix properties and an example are provided.
Laboratory investigation on hot mix asphalt using reclaimed asphalt pavement ...eSAT Publishing House
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology.
This document discusses steel fiber reinforced concrete (SFRC). SFRC increases the structural integrity of concrete by adding short, discrete steel fibers that are uniformly distributed and randomly oriented. The document outlines the materials used including cement, aggregates, water, and steel fibers. It describes the mix design process and percentages of steel fibers tested. Beams and cubes were cast with the concrete mixtures and cured before testing to determine the compressive and flexural strengths of the SFRC. The results and conclusions are summarized, with references provided.
This document summarizes a project report on the construction of roads at the National Institute of Technology in Warangal, India. It was completed by five students under the guidance of a faculty member. The report discusses the importance of roads for economic development and transportation. It provides an overview of the types of roads in India and the current status of the national highway system. It also describes the phases of road construction, materials used, equipment involved, and project management tools applied to the road projects at NIT Warangal.
This study evaluated the rutting performance of hot mix asphalt containing recycled asphalt mixes using a flow time test. Two mixes were designed using the Marshall mix design method - one without recycled asphalt pavement (RAP) and one with up to 40% RAP. Cylindrical samples were tested under a constant load at high temperature to measure flow time, which indicates rutting resistance. The results showed that mixes containing RAP had higher flow times, and therefore better rutting resistance, than the mix without RAP. Specifically, mixes with 10-20% RAP showed significantly increased flow times compared to the 0% RAP mix. The study suggests using RAP can improve rutting performance of as
Experimental investigation of rap modified asphalt binder and crushed rap ag...hsaam hsaam
This document presents an experimental investigation of reclaimed asphalt pavement (RAP) modified asphalt binder and crushed RAP aggregates. The study evaluates the physical properties of asphalt binder mixed with RAP at various proportions (10-50%) and tests the effect on properties like penetration, softening point, ductility and specific gravity. Aggregate tests like Los Angeles abrasion, crushing, shape and impact value are also conducted on crushed RAP aggregates. The results of mixing RAP with virgin binder and using crushed aggregates are discussed to analyze the recycling of RAP materials and minimize waste disposal.
Enrichment of the properties of Concrete mixes containing Reclaimed Asphalt P...IRJET Journal
This document discusses a laboratory investigation into improving the properties of concrete mixes containing reclaimed asphalt pavement (RAP) aggregates and silica fume. The study aims to determine the optimum replacement percentage of RAP aggregates in concrete and investigate how the addition of silica fume affects the compressive strength and properties of concrete with RAP. The document outlines the materials used, including RAP aggregates collected from a road near Ghansoli Railway Station in India. Concrete mixes were prepared with 30%, 45%, and 75% replacement of natural coarse aggregates with RAP. Test results found that 45% RAP reduced compressive strength by 15% compared to the control mix, while the addition of 4-10% silica f
Minor Project on design and analysis of flexible pavement with cement treated...PrashannaKumar2
This document is a minor project report submitted in partial fulfillment of a Bachelor of Technology degree in Civil Engineering. It discusses the design and analysis of a flexible pavement with a cement treated base course. The report was prepared by three students and submitted in October 2019 under the guidance of an associate professor. It includes the design of the flexible pavement sections based on IRC37 guidelines and analysis of the pavement layers under different traffic loads.
IRJET - To Study the effects of partially replacement of aggregate with RAP M...IRJET Journal
This document discusses a study on the effects of partially replacing aggregate with reclaimed asphalt pavement (RAP) material in dense bituminous macadam (DBM) design for flexible pavements. The study aims to promote more sustainable pavement construction by recycling RAP. Physical properties of mixtures containing different proportions of RAP aggregate are tested, including water absorption, stripping value, aggregate gradation, specific gravity, penetration, and Marshall stability. Test results indicate that replacing up to 30% of natural aggregate with RAP can meet design specifications and standards, offering potential cost savings while sustainably reusing demolition waste. The study concludes that RAP materials can successfully be used in flexible pavement bases and subbases when blended to achieve proper
INVESTIGATION ON FLY ASH AS A PARTIAL CEMENT REPLACEMENT IN CONCRETESk Md Nayar
The use of Portland cement in concrete construction is under critical review due to high
amount of carbon dioxide gas released to the atmosphere during the production of cement. In
recent years, attempts to increase the utilization of fly ash to partially replace the use of Portland
cement in concrete are gathering momentum. Most of this by-product material is currently
dumped in landfills, creating a threat to the environment.
Fly ash based concrete is a ‘new’ material that does not need the presence of Portland
cement as a binder. Instead, the source of materials such as fly ash, that are rich in Silicon (Si)
and Aluminium (Al), are activated by alkaline liquids to produce the binder.
This project reports the details of development of the process of making fly ash-based
concrete. Due to the lack of knowledge and know-how of making of fly ash based concrete in the
published literature, this study adopted a rigorous trial and error process to develop the
technology of making, and to identify the salient parameters affecting the properties of fresh and
hardened concrete. As far as possible, the technology that is currently in use to manufacture and
testing of ordinary Portland cement concrete were used.
Fly ash was chosen as the basic material to be activated by the geopolimerization process
to be the concrete binder, to totally replace the use of Portland cement. The binder is the only
difference to the ordinary Portland cement concrete. To activate the Silicon and Aluminium
content in fly ash, a combination of sodium hydroxide solution and sodium silicate solution was
used.
Manufacturing process comprising material preparation, mixing, placing, compaction and
curing is reported in the thesis. Napthalene-based superplasticiser was found to be useful to
improve the workability of fresh fly ash-based concrete, as well as the addition of extra water.
The main parameters affecting the compressive strength of hardened fly ash-based concrete are
the curing temperature and curing time, The molar H2O-to-Na2O ratio, and mixing time.
Fresh fly ash-based concrete has been able to remain workable up to at least 120 minutes
without any sign of setting and without any degradation in the compressive strength. Providing a
rest period for fresh concrete after casting before the start of curing up to five days increased the
compressive strength of hardened concrete.
The elastic properties of hardened fly ash-based concrete, i,e. the modulus of elasticity,
the Poisson’s ratio, and the indirect tensile strength, are similar to those of ordinary Portland
cement concrete. The stress-strain relations of fly ash-based concrete fit well with the expression
developed for ordinary Portland cement concrete.
IRJET- Laboratory Evaluation of Usage of Crumb Rubber & Plastic Wastes in Asp...IRJET Journal
This document summarizes a study on using crumb rubber and plastic wastes in asphalt concrete pavement. The study involved:
1) Testing the physical properties of bitumen, aggregates, and bitumen modified with crumb rubber.
2) Preparing semi-dense bituminous concrete mixes using the Marshall method with varying percentages of low density polyethylene (LDPE) and crumb rubber added to 60/70 grade bitumen.
3) Evaluating the mix design characteristics such as Marshall stability, flow value, density, air voids, and voids filled with bitumen.
The results showed that with the addition of LDPE and crumb rubber, the Marshall stability values and densities of the mixes
A Review on use of Bituminous Pavementwastes in Cement Concreteijtsrd
In general, aggregate make up 60 75 of concrete volume, so their selection is important, also they control concrete properties. Aggregate provide strength and wear resistance in these applications. Hence, the selection and proportioning of aggregate should be given careful attention. The aggregate is generally coarse gravel or crushed rocks such as limestone, or granite, along with a fine aggregate such as sand or stone dust. Bulk of pavement structure is formed by aggregate. This paper presents a review on the use of bituminous pavement wastes in cement concrete. This will help in achieving economy in road construction as well as saving environmental degradation in term of reduced mining and less pollution. Gulshan | Nitin thakur "A Review on use of Bituminous Pavementwastes in Cement Concrete" Published in International Journal of Trend in Scientific Research and Development (ijtsrd), ISSN: 2456-6470, Volume-3 | Issue-5 , August 2019, URL: https://www.ijtsrd.com/papers/ijtsrd28043.pdfPaper URL: https://www.ijtsrd.com/engineering/civil-engineering/28043/a-review-on-use-of-bituminous-pavementwastes-in-cement-concrete/gulshan
Structural design and economic evaluation of roller compacted concrete pavementSalih Taner YILDIRIM
Abut, Y., & Yildirim, S. T. (2017, October). Structural design and economic evaluation of roller compacted concrete pavement with recycled aggregates. In IOP Conference Series: Materials Science and Engineering (Vol. 245, No. 2, p. 022064). IOP Publishing.
Study of Mechanical Properties of Porous and Non-Porous Aggregate by Using Lo...IRJET Journal
This document discusses using plastic waste in road construction as a way to address pollution from plastic and increase the longevity and cost-effectiveness of roads. It reviews past research showing that mixing plastic with bitumen used in road surfaces increases strength properties like resistance to water damage. The authors aim to study using mixtures of bitumen, porous and non-porous aggregates, and different percentages of plastic waste, testing the properties. Their literature review found that plastic improves bitumen properties and road quality according to past studies. The conclusion is that using plastic waste in road construction could help solve plastic dumping while building stronger, more economical roads.
The Use of Reclaimed Asphalt Pavement as a Foundation for Pavements Based On ...IJERA Editor
This document summarizes a research study that aimed to determine the maximum percentage of reclaimed asphalt pavement (RAP) that can be used in mixtures for different types of pavement foundations according to the 2010 Indonesian National Standard specifications. The study involved laboratory testing of RAP mixtures containing 0-15% RAP combined with virgin aggregates. The results showed that RAP mixtures can be used for class A foundations at up to 3% RAP, class B foundations at up to 9% RAP, and class S foundations at up to 10% RAP while still meeting the specification requirements.
Experimental investigations on the performance of bituminous mixes with recla...eSAT Publishing House
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology.
Utilisation of RAP (Reclaimed Asphalt Pavement) Material Obtained By Milling ...IJERA Editor
Some practical options to use the RAP material in urban areas and thereby achieving economy in the construction besides solving the raised level of roads, effective disposal of RAP and above all using the principles of environment friendly Green technology that is: Reduce, Reuse and Recycle.
IRJET- Review on Mix Design of Emulsion Treated Reclaimed Asphalt PavementIRJET Journal
This document reviews different methods for recycling reclaimed asphalt pavement (RAP) and discusses the mix design of emulsion treated RAP. It begins by describing five common RAP recycling methods: hot mix plant recycling, hot in-place recycling, cold mix plant recycling, cold in-place recycling, and full depth reclamation recycling. It then discusses a specific project in India that used full depth reclamation to recycle existing asphalt up to 200mm depth, treating it with emulsion in a warm mix asphalt plant. The objectives of the project were to replace virgin aggregates and preserve the environment through a cost-effective and environmentally friendly mix. Finally, the document reviews several other studies that examined mix designs using
IRJET - Experimental Study on the Strength of Subgrade Layer of Road Pavement...IRJET Journal
This document presents the results of an experimental study on improving the strength of subgrade soil for road pavement using different admixtures. Laboratory tests were conducted to determine the California Bearing Ratio (CBR) of soil mixed with fly ash and cement. The CBR value was found to increase with the addition of 5-15% fly ash and 2-5% cement compared to plain soil. Mixing both 18% fly ash and 2% cement also increased the soil strength. The study aims to evaluate how these admixtures can enhance the subgrade soil strength for flexible pavement design.
Amendment of Sub-Grade Strength Using E-Waste and Rice Husk AshIRJET Journal
This document summarizes a study on amending sub-grade soil strength using e-waste and rice husk ash. The study aimed to improve weak soil as a supporting material for road sub-grades by adding waste products like e-waste and rice husk ash. The document outlines the methodology which included collecting materials, crushing e-waste, determining properties, and conducting California Bearing Ratio (CBR) tests on soil mixed with different ratios of e-waste and rice husk ash. The results showed that mixing soil with 10% rice husk ash and 5% e-waste achieved the highest CBR value of 8.5%, indicating improved sub-grade strength compared to untreated soil. The study concluded that stabilizing
Study of Partial Replacement of the Cement By GGBS & RHA and Natural Sand by ...IRJET Journal
This study investigated the effects of partially replacing cement with ground granulated blast furnace slag (GGBS) and rice husk ash (RHA), and partially replacing natural sand with quarry sand in concrete. The concrete samples were tested at 7 and 28 days for compressive strength, split tensile strength, and flexural strength. The results showed that replacing 60% of natural sand with quarry sand and a combination of 7.5% RHA with 22.5% GGBS provided good strength results. Using these industrial byproducts and quarry sand as partial replacements reduced the cost and environmental impact of concrete production. This research demonstrated that waste materials can be utilized to create more sustainable concrete.
IRJET- Review on Utilization of Partially Replacement of Cement and Sand ...IRJET Journal
This document summarizes a literature review on utilizing paper mill sludge and sugarcane bagasse ash as partial replacements for cement and sand in concrete. Several studies found that: 1) Cement can be replaced by 15% paper mill sludge or 10% sugarcane bagasse ash without significantly reducing strength; 2) Replacing up to 20% fine aggregate with sugarcane bagasse ash increases later-age strengths; 3) Maximum compressive strength is achieved with 15% cement replacement by paper mill sludge, then decreases at higher replacements. The reviewed project will produce concrete mixes with these replacements and test strengths at curing periods up to 28 days.
IRJET- Comparative Study on Partial Replacement of Cement with Quarry Dust an...IRJET Journal
This document presents a comparative study on the partial replacement of cement with quarry dust and rice husk ash in concrete. Tests were conducted on concrete with 0%, 5%, 15%, 25%, and 35% replacement to determine the compressive strength, split tensile strength, and flexural strength at 7 and 28 days. The results showed that compressive strength increased with up to 25% quarry dust replacement but decreased with rice husk ash replacement. Split tensile strength followed a similar trend while flexural strength was highest at around 15% replacement for both materials. Therefore, partial cement replacement with quarry dust or rice husk ash can improve some concrete properties but the optimal replacement percentage depends on the property and material used.
Similar to Performance studies on reclaimed asphalt SMA 2014 (20)
IRJET- Comparative Study on Partial Replacement of Cement with Quarry Dust an...
Performance studies on reclaimed asphalt SMA 2014
1. i
R.V. COLLEGE OF ENGINEERING, BANGALORE-
560059
(Autonomous Institution Affiliated to VTU, Belgaum)
PERFORMANCE STUDIES ON STONE MATRIX
ASPHALT WITH RECYCLED ASPHALT
PAVEMENT
PROJECT REPORT
Submitted by
Swathi L Gowda 1RV10CV033
Deepashree S 1RV11CV400
Souradip Datta 1RV10CV036
Under the Guidance of
Mr. Varuna M
Asst. Professor
Dept. of Civil,
RVCE
in partial fulfilment for the award of degree
of
Bachelor of Engineering
IN
DEPARTMENT OF CIVIL ENGINEERING
JAN – MAY 2014
2. ii
R.V. COLLEGE OF ENGINEERING, BANGALORE - 560059
(Autonomous Institution Affiliated to VTU, Belgaum)
DEPARTMENT OF CIVIL ENGINEERING
CERTIFICATE
Certified that the project work titled ‘Performance Studies on Stone Matrix
Asphalt with Recycled Asphalt Pavement’ is carried out by Swathi L Gowda
(1RV10CV033), Deepashree S (1RV11CV400), Souradip Datta(1RV10CV036),
who are bonafide students of R.V. College of Engineering, Bangalore, in partial
fulfilment for the award of degree of Bachelor of Engineering in Civil Engineering
of the Visvesvaraya Technological University, Belgaum during the year 2013-2014. It
is certified that all corrections/suggestions indicated for the internal assessment have
been incorporated in the report deposited in the departmental library. The project
report has been approved as it satisfies the academic requirements in respect of
project work prescribed by the institution for the said degree.
Mr. Varuna M, Dr. B S Satyanarayana,
Assistant Professor Principal
Dept. of Civil, RVCE RVCE, Bangalore
3. iii
R.VCOLLEGE OF ENGINEERING, BANGALORE - 560059
(Autonomous Institution Affiliated to VTU, Belgaum)
DEPARTMENT OF CIVIL ENGINEERING
DECLARATION
We, Swathi L Gowda (1RV10CV033), Deepashree S (1RV11CV400), Souradip
Datta(1RV10CV036), students of eighth semester B.E., Civil Engineering, hereby
declare that the project titled “Performance Studies on Stone Matrix Asphalt with
Recycled Asphalt Pavement” has been carried out by us and submitted in partial
fulfillment for the award of degree of Bachelor of Engineering in Civil. We do
declare that this work is not carried out by any other students for the award of degree
in any other branch.
Place: Bangalore Signature
Date: 02/06/2014
1. Swathi L Gowda
2. Deepashree S
3. Souradip Datta
4. iv
ACKNOWLEDGEMENT
We express our sincere regards and heartfelt gratitude to Mr. Varuna M, Assistant
Professor , Department of Civil Engineering, RVCE under whose guidance this study
was planned, executed and completed. His encouragement, interest and ideas were
source of inspiration and motivation for successful completion of this work.
We are grateful toDr.B.C.Udayashankar, Professor and Head, Department of Civil
Engineering, RVCE for encouraging the project.
We are grateful to our honorable Principal,Dr.B.S.Satyanarayana for giving us the
permission to conduct this project.
We are grateful to P.V.Srinath, Professor, Department of Civil Engineering, RVCE
and K Jagadish, Associate Professor, Department of Civil Engineering, RVCE for
providing valuable inputs for the projects.
We are deeply indebted to all the faculty members of Department of Civil
Engineering, RVCE for their knowledge advice and encouragement throughout the
course of study.
We are grateful to Mr. Shivaprakash for helping in conducting important
experimental works.
We are also grateful to our parents, our family members and all our friends for their
timely support and encouragement throughout the project.
.
5. v
ABSTRACT
Use of reclaimed asphalt pavements in hot mix asphalt mixtures has evolved into a
regular practice in many countries around the world. Use of these materials in the past
has proved to be economical and environmentally sound. Mixing RAP in virgin
materials has been greatly favored over virgin materials because of the increasing cost
of asphalt, scarcity of good quality aggregate, scarcity of asphalt and the ever
increasing need to preserve the environment. The literature survey contexts that use of
reclaimed asphalt pavement is effective in improving the performance which is equal
to or better than the virgin mixtures. Unfortunately, asphalt pavement recycling is yet
to take off in India despite the current ambitious road building program underway.
This has created a need to use RAP.
The purpose of this study is to determine performance analysis between varied
proportions of Virgin and RAP mixtures (i.e., 0, 10, 30 and 50%) for Stone matrix
asphalt mixes from standardized laboratory tests. RAP was brought from NH-7; basic
tests were done both on virgin and RAP materials to check the quality. Firstly, the
quantity of RAP and new aggregates will be in such a way that the resultant gradation
of aggregates confirms to the Stone Matrix Asphalt as per SP-79 and the total quantity
of asphalt binder is adjusted in such a way that it satisfies the desired asphalt binder
quantity of the target mix using the soft grade bitumen of VG-30 by using waste
engine oil as rejuvenator. Then RAP to new aggregate ratio will be adopted as 10:90,
30:70 and 50:50 and these proportions are assessed for their mechanical behaviour,
tensile strength, fatigue strength and compared with virgin mix. Based on the results
obtained in this study, best performance mix based on RAP percentages is adopted.
Savings in material costs with the inclusion of RAP will be determined.
Keywords – Reclaimed asphalt pavements, Stone matrix asphalt, Economic analysis.
6. vi
TABLE OF CONTENTS
Abstract v
List of Symbols, Acronyms and Nomenclature viii
List of Tables ix
List of Figures xi
1. Introduction 1
1.1 Background 1
1.2 Introduction 2
1.3 Literature Review 2
1.4 Benefits of asphalt recycling 4
1.5 Motivation 5
1.6 Objectives 5
1.7 Methodology 5
1.8 Organization of the Report 6
2. Theory and concepts 6
2.1 General 7
2.2 Methods of recycling pavements 7
2.2.1 Hot in place recycling 7
2.2.2 Cold recycling 8
2..2.3 Full depth reclamation 9
2.2.4 Hot mix recycling 10
2.3 Blending of recycled asphalt pavements 11
2.4 Gradation of recycled asphalt pavements 11
2.5 Mix design 12
2.6 Characteristics of RAP material 12
2.7 Stone matrix asphalt 12
2.8 Advantages of SMA 13
3. Methodology of mix design 14
3.1 Marshall method of mix design 14
7. vii
3.1.1 Individual gradation of aggregates 15
3.1.2 RAP replacement 16
3.1.3 Specimen preparation 16
3.2 Preparation of graphical plots 17
3.2.1 Relation between Bulk Density and Binder Content 18
3.2.2 Relation between Air Voids and Binder Content 18
3.2.3 Relation between VFB and Binder Content 18
3.2.4 Relation between Stability and Binder Content 18
3.2.5 Relation between Flow and Binder Content: 18
3.3 Selection of OBC 19
3.4 Selection of optimum RAP percentage 19
3.5 Indirect tensile test 19
4. Results
4.1 Tables and Graphs 21
4.2 Economic analysis 33
4.3 Conclusions 35
4.4 Scope for further studies 35
References 36
8. viii
LIST OF SYMBOLS, ACRONYMS AND
NOMENCLATURE
NHDP National Highway Development Program
SMA Stone Matrix Asphalt
RAP Reclaimed Asphalt Pavement
HMA Hot Mix Asphalt
RTS Retained Tensile Strength
ITS Indirect Tensile Strength
FDR Full Depth Reclamation
OGA Open Grade Asphalt
VFB Voids Filled With Bitumen
VMA Voids In Mineral Aggregates
9. ix
Table No. LIST OF TABLES Page
No.
Table 3.1 Individual gradation of aggregates 15
Table 3.2 Weight of virgin aggregates for 100% virgin specimen 15
Table 3.3 For RAP replacement 16
Table 3.4 Tests on virgin bitumen 21
Table 3.5 Tests on virgin aggregates 21
Table 3.6 Bitumen extraction and grading 21
Table 3.7 Tests on RAP bitumen 22
Table 3.8 Tests on RAP aggregates 22
Table 3.9 Determination of rejuvenating oil content 22
Table 3.10 Marshal Test results for virgin specimens 23
Table 3.11 Marshall test results for 10% rap 25
Table 3.12 Marshall Test results for 30% rap 28
Table 3.14 Marshall Test results for 50% rap 33
Table 5.1 Cost for Virgin mix 33
10. x
Table 5.2 Cost for 10% RAP 34
Table 5.3 Cost for 30% RAP 34
Table 5.4 Cost for 50% RAP 34
11. xi
LIST OF FIGURES
Figure no. Figure name Page No.
Figure 2.1 Hot in place recycling 8
Figure 2.2 Material deposition 9
Figure 2.3 Rejuvenating pavements 10
Figure 2.4 Asphalt batch plant 11
Figure 2.5 SMA and DGA 13
Figure 3.1 Marshall apparatus 17
Figure 3.2 ITS test 20
Figure 3.3 Bulk density v/s Binder content 23
Figure 3.4 Percentage Air voids v/s Binder content 23
Figure 3.5 Percentage VFB v/s Binder content 24
Figure 3.6 Stability v/s Binder content 25
Figure 3.7 Flow v/s Binder Content. 25
Figure 3.8 Bitumen content vs Bulk density 26
Figure 3.9 Bitumen content vs Voids filled with bitumen 26
12. xii
Figure 3.10 Bitumen content vs Air voids 27
Figure 3.11 Bitumen content vs Stability 27
Figure 3.12 Bitumen content vs Flow 28
Figure 3.13 Bitumen content vs Bulk density 39
Figure 3.14 Bulk density vs Air voids 29
Figure 3.15 Bulk density vs Stability 29
Figure 3.16 Bitumen content vs Flow 30
Figure 3.17 Bitumen content vs Voids filled with bitumen 30
Figure 3.18 Bitumen content vs Bulk density 31
Figure 3.19 Bitumen content vs Air voids 31
Figure 3.20 Bitumen percentage vs Voids filled with bitumen 32
Figure 3.21 Bitumen percentage vs Flow 32
Figure 3.22 Bitumen percentage vs Stability 32
Figure 3.23 ITS graph 33
13. Dept. Of Civil,RVCE 2013-2014 Page 1
CHAPTER 1
1. INTRODUCTION
1.1Background:
Road Transport in India accounts for 80% of passenger movement and 65% of freight
movement. With 4.3 million km of roads, India has the second largest road network in the
world. Only 50% of the roads are paved, even the paved length has inadequate design
standards. The current state of our nation’s transportation infrastructure is inadequate, and
many state and city municipalities do not have the funds to rehabilitate their road networks to
improve them to an acceptable level. National Highways Authority of India has prepared
plans involving an outlay of Rs. 2,20,000 crores under National Highways Development
Program (NHDP) and 10,000 km of expressways at a cost of Rs 1,00,000 crores are being
planned in order to develop the road infrastructure and to boost the economy in India. The
eleventh plan investment in roads and bridges is about Rs 2,78,658 crores which is about
13.57 % of total outlay.
The Vision 2020 targets the development of a core network of 40000 kms to serve its
industrial, agriculture and tourism industries. To meet the increasing traffic intensities and the
persistent regional disparities in the accessibility to good quality roads, it has been proposed
to increase the road density from the 1.09 km per sq km to 1.50 km per sq km and up
gradation of existing road network to increase the share of roads with carriage width of 2 lane
and above from the current 10.32% to 55%.
These mega road modernization exposes challenges of various concerns pertaining to
depletion of resources like good soil and aggregates, long lead to get good quality aggregates
and increase in fuel consumption etc, and also the increasing cost for the supply of bitumen,
is dependent on foreign sources, and the energy requirement for processing new materials is
becoming costlier every day.
Recycling of existing bituminous mixes are the only alternatives, through the reuse of
aggregates and bitumen. Recycling of asphalt pavements is one of the effective and proven
rehabilitation processes. Estimated world production of asphalt in 2007 is about 1.6 trillion
metric tons of asphalt was produced worldwide. Out of which Asia produced 495 million
14. Dept. Of Civil,RVCE 2013-2014 Page 2
metric tons of asphalt, nearly 31 percentage of total production [The asphalt paving industry:
a global perspective second edition 2008].Use of the recycled materials in the road
construction has been favoured over virgin materials in the light of increasing cost of
bitumen, scarcity of good quality aggregates and the priority towards preservation of the
environment. Considering the material and construction cost only, it is estimated that using
recycled materials, saving ranging from 14 to 34% can be achieved.
Due to heavy and continuously moving traffic we find rutting of roads and also their
durability is reduced. To tackle these problems new pavement mix called the Stone Matrix
Asphalt (SMA) was formulated. SMA comprises of large amount of coarse aggregates and
hence there will be more stone-to-stone contact which gives a better network to carry the
traffic load.
1.2 Introduction
In this project we have prepared stone matrix asphalt mixes using a certain percentage of
recycled asphalt materials (10%, 30%, 50% RAP), and made specimens. Later the specimens
were tested for marshal stability, for the mix which showed highest stability Indirect Tensile
Strength was performed and at the end of the project economic analysis was done to
determine the cost saved.
1.3 Literature reviews
Recycling of asphalt pavements is a technology developed to rehabilitate and/or replace
pavement structures suffering from permanent deformation and evident structural damage
[1]. In this context, according to [2], the reclaimed asphalt pavement (RAP) is one of the
most reclaimed materials in the world. The first data documented on the use of RAP for the
construction of new roads date back to 1915 [3]. However, the actual development and rise of
RAP usage occurred in the 1970’s during the oil crisis, when the cost of the asphalt binder (or
asphalt) as well as the aggregate shortages where high near the construction sites [4]. Later,
in 1997, with the Kyoto Protocol adaptation by parties and implementation in 2005, recycling
received major attention and broader application in the road construction industry [5].
Several authors state that diverse methods for recycling of asphalt pavements are suitable
including: hot recycling in plant, hot-recycling "in situ", cold-recycling "in situ", and others
[6, 1, and 7]. Nevertheless, hot recycling is one of the most widely techniques used
nowadays, where virgin materials and RAP are combined indifferent proportions and sizes
[8]. Studies in Europe and the United States have concluded that over 80% of the reclaimed
15. Dept. Of Civil,RVCE 2013-2014 Page 3
material is reused in the construction of roads, but regulations are still strict allowing
inclusion of RAP in proportions ranging between 5 and 50% for production of new hot mix
asphalt (HMA) mixtures [9].
Studies performed to determine the response of HMA mixtures with RAP replacements
between 0 and 40%and fabricated with different asphalts, have shown the low moisture
damage susceptibility of the new HMA mixtures (i.e., based on retained tensile strength
(RTS) values above 95%; Superpave criteria-ASTM D4867).
Similarly, it was found that the resilient modulus values increase regardless of the tests
temperature (-18, 0, 25,and 32 °C), type of asphalt (PG-46-40, PG-52-34, and PG-58-28), and
addition of RAP (15, 30, and 40%) [10].
According to [2], the incorporation of 40% RAP in HMA mixtures created no modification
on the mixture properties. Conversely, when values higher than 40% were included, the
mixture properties changed drastically.
In general, when higher percentages of RAP were used, evident reductions on the relative
energy loss—computed based on the load-displacement curve determined for the indirect
tensile test—were reported with possible appearance of premature distresses. The latter can
be related to possible moisture damage that may affect the mechanical response (i.e.,
permanent deformation- and fatigue-response) and mixture performance.
Recent researches [1, 8, 11, 12], have established that RAP replacement at proportions above
50% are feasible to produce new HMA mixtures, obtaining satisfactory results in the
mechanical properties. Similar fatigue curves were determined for HMA mixtures fabricated
with low penetration asphalt (13/22) and HMA mixtures with60% RAP replacement.
Likewise, the susceptibility to moisture damage was low (RTS values close to 95%). In
addition, the HMA mixtures with RAP replacement increased in 50% the indirect tensile
strength (ITS) as compared to that of the HMA mixtures fabricated with virgin materials. The
energy dissipated during the ITS testalso increased by 100% in the HMA mixtures with RAP
replacement.
Olard et al. (2008) [13] assessed HMA mixtures with high recycling rates (i.e., >50% RAP
replacement) for warm- and HMA-mixture production and stated that RAP foster positive
environmental impacts, including that it:(i) can be done in an asphalt plant or in-place, (ii)
reuses existing materials thus eliminating disposal problems(saving or diminishing land
requirements in populated countries), (iii) saves costly materials and in some countries rare,
16. Dept. Of Civil,RVCE 2013-2014 Page 4
hard to find good aggregates, (iv) can correct both asphalt content and aggregate gradation of
an existing HMA mixture, and (v) produces a stable pavement structure at a lower cost than
that associated with conventional methods.
Based on the positive experiences and outcomes from global use of HMA mixtures with RAP
inclusion, it can be inferred that relevant results could be obtained from application of this
technology in developing countries such as India. Similarly, the same concerns rose by the
Kyoto protocol and other global policies with regard to air pollution must be taken into
account to minimize risks on human health and ensure environmental quality.
1.4 Benefits of Asphalt Recycling:
The bituminous pavement rehabilitation alternatives are mainly overlaying, recycling and
reconstruction. In the recycling process the material from deteriorated pavement, known as
recycled asphalt pavement (RAP), is partially or fully reused in fresh construction.
It is important to recognize that asphalt recycling is a powerful method to rehabilitate
pavements. When properly carried out, it has substantial long term economic benefits.
1. Reuse and conservation of non-renewable natural resources.
2. Preservation of the environment and reduction in land filling.
3. Energy conservation.
4. Reduction in user delays during construction.
5. Improved pavement smoothness.
6. Cost saving over traditional rehabilitation methods.
7. Improved pavement physical properties by modification of existing aggregate gradation,
and asphalt binder properties.
8. Conserves aggregate and asphalt, which are very important in areas where aggregate and
asphalt are in short of supply or where haul distances to remote locations are excessively
long.
9. With proper design and construction control of recycled hot mix, the performance of the
recycled pavement is equal to traditional method.
17. Dept. Of Civil,RVCE 2013-2014 Page 5
1.5 Motivation of Present Study:
In India, about 15,000 tonnes of aggregates are required per kilometre of highway. A
standard project of National Highway Development Project (NHDP) of 60 km road
improvement requires 20 lakh ton of material. In India, mostly the old pavement materials are
dumped into landfills. Landfills have been identified as the largest source of methane caused
by humans. The material costs constitute about 40% of total construction cost of the project.
The construction cost is growing exponentially mainly due to increase in the cost of
materials. Recycling of existing bituminous mixes results in substantial savings through the
reuse of aggregates and bitumen. Use of the recycled materials in the road construction has
been favoured over virgin materials in the light of increasing cost of bitumen, scarcity of
good quality aggregates and the priority towards preservation of the environment. This study
makes an attempt at presenting a comprehensive view of one of such technology called
recycled asphalt pavements. It’s high time that the recycling process need to be implemented
owing to their major advantages over overlaying process. These are today’s burning issues
and have become the purpose of the study.
1.6 Objective
1. To determine the basic engineering properties of the Virgin bitumen and Virgin
aggregate.
2. To determine the basic engineering properties of Reclaimed Aggregate and binder
after extraction and Recovery.
3. To carry out the blending of RAP and Virgin aggregates for 10%, 30%, 50% RAP
content as per MORTH V revision, satisfying SMA gradation.
4. To carry out the mix design for 10%, 30%, 50% reclaimed mixes with virgin mixes
5. To study the influence of reclaimed materials on the stability, tensile strength, and
fatigue life of SMA mix through laboratory experiments.
6. To workout the economics of recycling of bituminous pavement materials.
1.7 Methodology:
The methodology for this study involved the following major tasks: Literature Review,
experimental design and materials selection, laboratory testing program, laboratory test result
18. Dept. Of Civil,RVCE 2013-2014 Page 6
analysis, Marshall Mix design are carried out for virgin and RAP mixtures as per asphalt
institute (MS-II) concept and MoRT&H. Comparison and evaluation of the Marshall
properties, indirect tensile strength, fatigue life and economic analysis for Virgin asphalt
mixtures and various RAP combined with virgin aggregate mixtures i.e., 20, 30, and 50%
finally conclusions and recommendations for future work are present.
1.8 Organization of Thesis:
Chapter 1 includes the brief introduction to the project, the literature review for the project
along with benefits of asphalt recycling, motivation for the study and objectives of the project
and brief summary of the methodology.
Chapter 2 consists of theory and concepts necessary for the project including various type of
asphalt recycling. Their blending and gradation along with the mix design .It also contains
theory on characteristics of RAP, advantages of SMA.
Chapter 3 consists of the methodologies of various processes conducted during the length of
the project including preparation of specimens, Marshall stability test, ITS test etc.
Chapter 4 consists of results and discussions where the results are tabulated and the graphs
are displayed along with the economic analysis, outcomes and scope for further studies.
19. Dept. Of Civil,RVCE 2013-2014 Page 7
CHAPTER 2
2. THEORY AND CONCEPTS
2.1 General:
This chapter describes the theory and concepts behind the present study which includes the
concepts of recycled asphalt pavements technology, laboratory principles.
2.2 Methods of Recycling Pavements:
The common types of recycling operations include Warm mix recycling, Hot In-place
Recycling (HIR), Cold In-place Recycling (CIR), and Full Depth Reclamation (FDR).
Among this, hot mix recycling is very commonly used for producing Hot Mix Asphalt
(HMA). Hot in- place and Cold in-place recycling are commonly used for preventive
maintenance operations, whereas full depth reclamation is generally used for rehabilitation
work. Based on the process adopted in recycling of bituminous mixes, the methods can be
classified as central plant recycling and in-situ recycling.
2.2.1 Hot In Place Recycling:
Hot in place recycling has been described as an insitu method that rehabilitates deteriorated
asphalt pavements and thereby minimizes the use of new materials. Basically this process
consists of four steps: (1) Softening of the asphalt pavement surface with heat (2)
Scarification and/or mechanical removal of the surface material (3) Mixing of the material
with recycling agent, asphalt binder, or new mix and (4) Lay down and paving of the
20. Dept. Of Civil,RVCE 2013-2014 Page 8
reclaimed mix on the pavement surface. The primary purpose of hot in -place recycling is to
correct surface distresses.
Fig 2.1 Hot in place recycling
2.2.2 Cold Recycling:
They can be divided into two main parts-cold in-place recycling and cold milling. Cold
milling is used for obtaining materials for hot mix recycling.
(i) Cold Milling: It is a method of automatically controlling the removal of pavement to a
desired depth using specially designed equipment and restoration of the surface to a specified
grade and slope, devoid of bumps, ruts and/or other imperfection.
The modern cold milling equipment has tungsten carbide teeth fixed on drums, with
adjustable cutting width for a variety of pavements and excellent maneuverability for
different milling situations.
(ii) Cold In-place Recycling (CIR): It is defined as a rehabilitation technique in which the
existing pavement materials are reused insitu. The materials are mixed together without the
application of heat. The reclaimed asphalt pavement material is obtained by milling or
crushing the existing pavement. Fresh aggregate or recycling agent or both are added to the
RAP material, which is subsequently laid and compacted. Cold in place recycling can restore
the original profile of old pavements, eliminate existing wheel ruts, restore the crown and
cross slopes and eliminate pot-holes and rough areas.
21. Dept. Of Civil,RVCE 2013-2014 Page 9
Fig 2.2 after being processed, the material is deposited onto the roadway in a windrow.
2.2.3 Full Depth Reclamation (FDR):
It has been defined as a recycling method where all of the asphalt pavement section and the
pre-determined amount of underlying materials are treated to produce a stabilized base
course. Different varieties of additives, such as asphalt emulsions and chemical agents such
as lime are added to obtain an improved base. The main five steps in this process are
pulverization, addition of additive, shaping the mixed material, compaction and the
application of a surface or a wearing course. This method is normally performed to a depth of
100 to 300 mm. The major advantages and benefits of full depth reclamation are as follows:
1. The structure of the pavement can be improved significantly without changing the
geometry of the pavement and shoulder reconstruction.
2. It can restore old pavement to the desired profile, eliminate wheel ruts, restore crown and
slope, and eliminate pot holes, irregularities and rough areas.
22. Dept. Of Civil,RVCE 2013-2014 Page 10
Fig 2.3 Rejuvenating existing pavement structure by stabilizing for FDR
2.2.4 Hot Mix Recycling:
It is a method in which RAP is combined with new aggregates and an asphalt cement or
recycling agent to produce HMA. The RAP can be obtained by milling with a rotary drum
cold milling machine.RAP from different sources containing different asphalt contents and
aggregates with different gradations should be stockpiled separately. The RAP cannot be
processed in standard drum mix plant since excessive blue smoke is produced when the RAP
comes in contact with the burner flame. Majority of the smoke problem is caused by the light
oils in soft grades of asphalt binder used to rejuvenate the aged asphalt in the RAP. The
smoke problem could be solved by various processes such as lowering the HMA plant’s
production rate, decreasing the moisture content of the RAP, lowering the discharge
temperature of the reclaimed mix, introducing additional combustion air, and decreasing the
percentage of RAP. Hot mix recycling plant is shown in Figure-2.1.
23. Dept. Of Civil,RVCE 2013-2014 Page 11
Fig 2.4 Asphalt batch plant with RAP in feed for hot recycling
2.3 Blending Of Recycled Asphalt Pavements:
Although several research studies have reported the use of RAP and its performance in new
asphalt mixtures, none have emphasized the study on how much old asphalt is actually
blended with new mixtures during the mixing process. The studies conducted on a blended
mixture consisting of 20% RAP revealed that only a portion of the aged asphalt participated
in the remixing process while the other portions formed a stiff coating around the RAP
aggregates and RAP behaved as a ―composite black rock. Despite similarities between
producing virgin asphalt mixtures and RAP asphalt mixtures there are challenges for
maximizing RAP usage. Generally the guidelines are based on the assumption that complete
blending occurs between virgin and new mixtures, but later it was understood that the amount
of blending that occurs was somewhere between complete blending and no blending;
however there is no actual methods available to accurately determine the amount of blending
that occurs.
2.4 Gradation of Recycled Asphalt Pavements:
Designing mixes containing RAP requires special attention to ensure minimum Voids in
Mineral Aggregates is met and the aggregate gradation is not significantly altered by the
addition of fines associated with RAP materials. RAP is somewhat finer than virgin
aggregate, therefore it is recommended that RAP used in recycled asphalt should be as coarse
as possible and the fines (< 0.075mm) should be minimized. RAP crushing during production
24. Dept. Of Civil,RVCE 2013-2014 Page 12
is recommended to minimize the fracture of coarse aggregate and excess fines generation as
high fines content leads to rutting due to low stability. The RAP should be free of foreign
materials such as broken concrete or other contaminants.
2.5 Mix Design:
The basic objective of the recycled mix design is to know the best constituent proportions
between the RAP, virgin binder and new aggregates. The total binder content of the recycled
mix was found out by some preliminary estimation and iterative mix design process done.
The average asphalt binder content of the RAP and the gradation of the old aggregates
present in RAP were found out. The constituent proportions calculated from the equations
were numerically identical to that of calculated as per Asphalt Institute. In the study, the
proportion between the aged and virgin binder, percentage of binder present in RAP and the
percentage of total binder demand of the recycled mix were known. From this percentage of
virgin bitumen and RAP to be added to obtain the recycled mix was estimated.
2.6 Characteristics of Rap Material:
The important characteristic of RAP material that would greatly influence the properties and
performance of the reclaimed mix is the stiffness of its binder. The recovered RAP binder is
more viscous and has lower penetration values than virgin binders due to ageing. The effects
of ageing are caused by chemical changes within the binder. Asphalt bituminous binder
exhibits two stages of ageing namely, short term and long term.
2.7 Stone Matrix Asphalt
Stone mastic asphalt (SMA), also called stone-matrix asphalt, was developed in Europe
(Germany) in the 1960s. It provides a rut resistant, durable surfacing material, suitable for
heavily trafficked roads. SMA has found use in EU, Australia, the United States, and Canada
as a durable asphalt surfacing option for residential streets and highways. SMA has a high
coarse aggregate content that interlocks to form a skeleton that resists
permanent deformation. The stone skeleton is filled with a mastic of bitumen and filler to
which fibres are added to provide adequate stability of bitumen and to prevent drainage of
binder during transport and placement. Typical SMA composition consists of 70−80% coarse
aggregate, 8−12% filler, 6.0−7.0% binder, and 0.3 per cent fibre.
25. Dept. Of Civil,RVCE 2013-2014 Page 13
Fig 2.5 Stone Matrix Asphalt and Dense Graded Asphalt
2.8 Advantages of Stone Matrix Asphalt
1. SMA provides a durable and rut resistant wearing course.
2. The surface texture characteristics of SMA are similar to Open Graded Asphalt
(OGA) so that the noise generated by traffic is lower than that on DGA but equal to or
slightly higher than OGA.
3. SMA can be produced and compacted with the same plant and equipment available
for normal hot mix, using the above mentioned procedure modifications.
4. SMA may be used at intersections and other high traffic stress situations where OGA
is unsuitable.
5. SMA surfacing may provide reduced reflection cracking from underlying cracked
pavements due to the flexible mastic.
26. Dept. Of Civil,RVCE 2013-2014 Page 14
CHAPTER 3
3. METHODOLOGY OF MIX DESIGN
3.1 Marshall Method of Mix Design:
In this stage, the bitumen and aggregate quantities to fulfill the gradation and volumetric
requirements of reclaimed mix will be determined for SMA. The mix design was carried out
in two phases. The first phase concentrates on the mix design of virgin materials as per mid
gradation method by Marshall Mix design method. In the later phase, the virgin materials
were blended with RAP of different proportions to meet the graduation requirement of the
mix SMA.
The step by step procedure has been carried out as indicated in the design procedure and the
steps involved are
1. Individual gradation of aggregate
2. RAP replacement
3. Specimen preparation
4. Specimen testing
27. Dept. Of Civil,RVCE 2013-2014 Page 15
3.1.1 Individual Gradation Of Aggregates :
Table 3.1
In our project we are preparing specimens for binder course.
Table 3.2 weight of virgin aggregates for 100% virgin specimen
IS Sieve (mm) Cumulative %
by weight of
total aggregate
passing
Passing at mid
point gradation
Total virgin
aggregate %
Total weight of
aggregates in
gm
26.5-19 100 100 0 0
19-13.2 90-100 95 5 60
13.2-9.5 45-70 57.5 37.5 450
9.5-4.75 25-60 42.5 15 180
4.75-2.36 20-28 24 18.5 222
2.36-1.18 16-24 20 4 48
1.18-0.6 13-21 17 3 36
0.6-0.3 12-18 15 3 36
0.3-0.075 10-20 15 3 36
0.075 8-12 10 4 48
28. Dept. Of Civil,RVCE 2013-2014 Page 16
3.1.2 RAP Replacement:
Table 3.3 For RAP replacement
10% RAP 30% RAP 50% RAP
Wt of virgin
aggregates
in gms
Wt of RAP
aggregates
in gms
Wt of virgin
aggregates
in gms
Wt of RAP
aggregates
in gms
Wt of virgin
aggregates
in gms
Wt of RAP
aggregates in gms
0 0 0 0 0 0
56.4 3.6 42 18 49.2 10.8
411.6 38.4 258 192 334.8 115.2
163.2 16.8 96 84 129.6 50.4
190.8 31.2 66 156 128.4 93.6
39.6 8.4 6 42 22.8 25.2
33.4 2.4 24 12 28.8 7.2
33 2.4 24 12 28.8 7.2
31.2 4.8 12 24 21.6 14.4
45.5 2.4 36 12 40.8 7.2
3.1.3 Specimen Preparation
Stone matrix asphalt mix samples were prepared by using 50 blows of Marshall hammer on
each face at different percentages of binder content varying from 5 to 6.5 progressing in 0.5%
increment. Three specimens were cast for each binder content they are then tested for
Marshall properties such as density, stability, flow, air voids, voids filled with bitumen
(VFB), voids in mineral aggregate (VMA).
Approximately 1200gm of aggregates and filler is heated to a temperature of 175-190o
C.
Bitumen is heated to a temperature of 121-125o
C with the first trial percentage of bitumen
(say 5.5 or 6% by weight of the mineral aggregates). The heated aggregates and bitumen are
thoroughly mixed at a temperature of 154-160o
C. The mix is placed in a preheated mould and
compacted by a rammer with 50 blows on either side at temperature of 138o
C to 149o
C. The
weight of mixed aggregates taken for the preparation of the specimen may be suitably altered
to obtain a compacted thickness of 63.5+/-3 mm. Vary the bitumen content in the next trial
29. Dept. Of Civil,RVCE 2013-2014 Page 17
by +0:5% and repeat the above procedure. Number of trials is predetermined. The prepared
mould is loaded in the Marshall test setup as shown in the figure.
. While the stability test is in progress dial gauge is used to measure the vertical deformation
of the specimen. The deformation at the failure point expressed in units of 0.25 mm is called
the Marshall Flow value of the specimen.
Figure 3.1 Marshall stability Apparatus
3.2 Preparation of Graphical Plots:
The average value of the above properties is determined for each mix with different bitumen
content and the following graphical plots are prepared:
1. Binder content versus corrected bulk density.
2. Binder content versus air voids(VV)
3. Binder content versus voids filled with bitumen (VFB).
4. Binder content versus stability
5. Binder content versus flow
30. Dept. Of Civil,RVCE 2013-2014 Page 18
3.2.1 Relation between Bulk Density and Binder Content:
Relation between bulk density and binder content for virgin bitumen (VG-30) is as shown in
the graph.
The variation of Bulk density with increase in the binder content is as shown in the Figure.
As the binder content increases density also increases up to a certain binder content and
reaches a maximum point then it decreases on further increase in the binder content.
3.2.2 Relation between Air Voids and Binder Content:
Relation between air voids and binder content for virgin bitumen (VG-30) is as shown in the
graph.
The graph of Air Voids in the Aggregate and the binder content is as shown in the figure.
With the increase in bitumen content, VV of Marshall sample decreases, as bitumen replaces
the air voids present in the mix.
3.2.3 Relation between VFB and Binder Content:
Relation between voids filled with bitumen and binder content for virgin bitumen (VG-30) is
as shown in the figure.
The graph of Voids Filled with Bitumen and the binder content is as shown in the figure.
With the increase in bitumen content, VV of Marshall sample decreases, as bitumen replaces
the air voids present in the mix and subsequently VFB increases with the increase in the
bitumen content.
.
3.2.4 Relation between Stability and Binder Content:
Relation between stability and binder content for virgin bitumen (VG-30) is as shown in the
figure.
The variation of the stability with the binder content is as shown in the figure.
Stability value increases with the increase in the bitumen content, as the aggregate-bitumen
bond gradually gets stronger. But with further increase in the bitumen content, the applied
load is transmitted as hydrostatic pressure, keeping the friction across the contact points of
aggregates immobilized. This makes the mix weak against plastic deformation and the
stability falls.
3.2.5. Relation between Flow and Binder Content:
Relation between flow and binder content for virgin bitumen (VG-30) is as shown in the
figure.
31. Dept. Of Civil,RVCE 2013-2014 Page 19
The variation of the flow with the binder content is as shown in the figure.
The flow value increases with the increase in bitumen content. The increase is slow initially,
but later the rate increases with the increase in bitumen content.
3.3 Selection of OBC:
The optimum binder content has been taken as the average of the median of air voids (4%),
peak of bulk density and peak of stability.
3.4 Selection of optimum RAP percentage:
Optimum percentage of RAP was found out after performing marshal stability test. It was
found that 30% RAP and 70% virgin mix was the best mix.
3.5 Indirect Tensile Strength Test:
Indirect tensile strength test was performed on 100% virgin mix and 30% RAP, 70% virgin
aggregate mix.
The Indirect Tensile Test is performed by loading a cylindrical specimen with a single or
repeated compressive load, which acts parallel to and along the vertical diametric plane. This
loading configuration develops a relatively uniform tensile stress perpendicular to the
direction of the applied load and along the vertical diametric plane, which ultimately causes
the specimen to fail by splitting along the vertical diameter. The Indirect Tensile Test is one
of the most popular tests used for hot bituminous mixture characterization in evaluating
pavement structures.Figure-3.2 shows the schematic representation of indirect tensile strength
test assembly.
Test Procedure for Conducting Indirect Tensile Strength Test:
1. The test specimens are prepared at the optimum bitumen content using Marshall Method
mix design for appropriate mix as per MoRT&H specifications.
2. The height of the specimens is noted down. Each set of specimens was tested at test
temperature of 250C to determine their indirect tensile strength.
32. Dept. Of Civil,RVCE 2013-2014 Page 20
3. The load at failure was recorded and the indirect tensile strength was computed using the
relation given below.
4. Indirect tensile stress: σ x = (2 x P) / (π x D x t)
Where: σ x = Horizontal stress (N/mm2), P= Failure load (N), D= Diameter of the specimen
(mm), t=Height of the specimen (mm).
Figure 3.2 Schematic representation of indirect tensile strength test.
33. Dept. Of Civil,RVCE 2013-2014 Page 21
CHAPTER 4
4. RESULTS
Table 3.4 Tests on virgin bitumen
Properties Obtained value
Permissible
Limit
Specification
Penetration at
25°c,5sec
65 60-70 IS -1203:1978
Softening
point(R&B),°C
53 45-55 IS -1205:1978
Flash point, °C 235 175 min. IS -1448:1969
Specific gravity 1.01 0.99 min. IS -1202:1978
Table 3.5 Tests on virgin aggregates
Sl.no Properties Conventional
aggregate
Requirements as per table
500-14MORT&H(IV)
specifications
1 Aggregate impact value(%) 17.6 Max 27%
2 Aggregate crushing value(%) 24.9 Max 30%
3 Water absorption of aggregates(%) 0.55 Max 2%
4 Specific gravity of aggregate 2.5 2.5-3
5 Flakiness and elongation index
(combined index)
28.7 Max 30%
From the tests performed on virgin bitumen and virgin aggregates, we can conclude that the
they are suitable for usage since they confirm to the standard specifications.
Table 3.6 Bitumen extraction and grading
Sl. no Weight of RAP in kg Bitumen obtained in
g
Percentage bitumen
1 1 39.7 3.97
2 1.5 55.2 3.68
34. Dept. Of Civil,RVCE 2013-2014 Page 22
Hence, the total quantity of bitumen in the RAP used is 3.825%
Table 3.7 Tests on RAP bitumen
Sl.no properties Rap binder PERMISSIBLE
LIMIT
1 penetration value of bitumen
@25 0
C
45 60-70
2 softening point 0
C 48 45-55
From the above table, we can conclude that the recycled binder has lost its properties due to
aging and hence has to be rejuvenated.
Table 3.8 Tests on RAP aggregates
The RAP aggregates hence confirm to the MORTH requirements.
Table 3.9 Determination of rejuvenating oil content
Sl. No. Percentage rejuvenating oil Penetration value
1 0 43
2 0.05 64
3 0.1 83
The virgin binder used is of grade 60/70 and hence the penetration value has to be between
60 and 70. Thus, the optimum percentage of rejuvenating oil would be 0.05%.
Sl.no Properties Conventional
aggregate
Requirements as per table
500-14MORT&H(IV)
specifications
1 Aggregate impact value(%) 19 Max 27%
2 Water absorption of
aggregates(%)
0.3 Max 2%
3 Specific gravity of
aggregate
2.4 2.5-3
4 Flakiness and elongation
index (combined index)
25 Max 30%
45. Dept. Of Civil,RVCE 2013-2014 Page 33
Table 3.14 ITS test results
TEMP ITS CONV
ITS 30% RAP
25 0.88 0.942
30 0.809 0.9
Fig 3.23 ITS graph
4.2 ECONOMIC ANALYSIS
In the present study an attempt is made to recycle the paving mixes and work out the cost
involved for recycling.
Furtherly, A comparative assessment is made by computing the cost for the conventional as
well as RAP mixes. A typical example for one kilometer length for two lane highway is
considered for cost analysis. The costs are calculated based on the schedule of rates of Govt.
of Karnataka. The details of economic analysis are given below.
Table 5.1 Cost for Virgin mix
Particular
s
Lengt
h
(m)
Widt
h
(m)
Dept
h
(m)
Qty. Of
aggregate
s
(m3
)
Qty. Of
Bitume
n
(m3
)
Qty. Of
virgin
material
s
(m3
)
Rate/m
3
Amount(Rs.
)
SMA 1000 7 0.1 700 42 742 9436 7001512
Total
0.8
0.82
0.84
0.86
0.88
0.9
0.92
0.94
0.96
24 26 28 30 32
StressMPa
Temperature
ITS
CONVENTIONAL
ITS 30% RAP
46. Dept. Of Civil,RVCE 2013-2014 Page 34
Table 5.2 Cost for 10% RAP
Particular
s
Lengt
h
(m)
Widt
h
(m)
Dept
h
(m)
Qty. Of
aggregate
s
(m3
)
Qty. Of
Bitume
n
(m3
)
Qty. Of
virgin
material
s
(m3
)
Rate/m
3
Amount(Rs.
)
Milling 1000 9 0.1 - - 990 36 35640
SMA 1000 7 0.1 700 42 668 9436 6303248
Total 6338888
Table 5.3 Cost for 30% RAP
Particular
s
Lengt
h
(m)
Widt
h
(m)
Dept
h
(m)
Qty. Of
aggregate
s
(m3
)
Qty. Of
Bitume
n
(m3
)
Qty. Of
virgin
material
s
(m3
)
Rate/m
3
Amount(Rs.
)
Milling 1000 9 0.1 - - 990 36 35640
SMA 1000 7 0.1 700 42 520 9436 4906720
Total 4942360
Table 5.4 Cost for 50% RAP
Particular
s
Lengt
h
(m)
Widt
h
(m)
Dept
h
(m)
Qty. Of
aggregate
s
(m3
)
Qty. Of
Bitume
n
(m3
)
Qty. Of
virgin
material
s
(m3
)
Rate/m
3
Amount(Rs.
)
Milling 1000 9 0.1 - - 990 36 35640
SMA 1000 7 0.1 700 42 371 9436 3500756
Total 3536396
After analyzing the economic analysis, the percentage of cost saving realized from the
recycled mixes of 10%, 30%, and 50% in comparison with virgin mix(0% RAP) are
19%,30%,51% respectively are found to be reduction in total cost.
47. Dept. Of Civil,RVCE 2013-2014 Page 35
4.3 Conclusions
• Based on the Marshall properties, the SMA mixes prepared with RAP material of 10,
30, and 50% shows higher stability when compared with the conventional virgin
mixes (0%).
• Based on the Marshall test results, the SMA mixes prepared with RAP materials of
10%, 30% shows all the Marshall properties of the mixes are well within the specified
limit.
• Indirect tensile strength of SMA mixes prepared with RAP materials shows higher
tensile strength at 25ºC when compared with SMA virgin mix.
• The saving can be realized from utilization of recycled materials as per the
methodology, the reduction in the total cost is 10, 30, and 51% comparing with the
virgin mixes.
4.4 Scope for further studies
• In the present study, the various tests were carried out for 0, 20, 30, and 50% RAP
materials. However various other percentages can be evaluated.
• To know the realistic results and performance accurately 100% RAP materials can be
evaluated.
• Various other binders can be used.
• Semi Field test track studies need to be carried out for validating the performance of
the RAP mixes.
48. Dept. Of Civil,RVCE 2013-2014 Page 36
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