User Guidelines for Waste and Byproduct Materials in Pavement Construction
PORTLAND CEMENT
CONCRETE PAVEMENT |
Application Description |
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INTRODUCTION
Portland cement concrete (PCC) pavements (or rigid pavements) consist of a PCC slab that is usually supported by a granular or stabilized base, and a subbase. In some cases the PCC slab may be overlaid with a layer of asphalt concrete.
Portland cement concrete is produced at a central plant and transported to the job site in transit mixers or batched into truck mixers directly and then mixed at the project site. In either case, the PCC is then dumped, spread, leveled, and consolidated, generally using concrete slip-form paving equipment.
MATERIALS
Basic components of PCC include coarse aggregate (crushed stone or gravel), fine aggregate (usually natural sand), Portland cement, and water. The aggregate functions as a filler material, which is bound together by hardened Portland cement paste formed by chemical reactions (hydration) between the Portland cement and water. In addition to these basic components, supplementary cementitious materials and chemical admixtures are often used to enhance or modify properties of the fresh or hardened concrete.
Concrete Aggregate
The coarse and fine aggregates used in PCC comprise about 80 to 85 percent of the mix by mass (60 to 75 percent of the mix by volume). Proper aggregate grading, strength, durability, toughness, shape, and chemical properties are needed for concrete mixture strength and performance.
Portland Cement and Supplementary Cementitious Materials
Portland cements are hydraulic cements that set and harden by reacting with water, through hydration, to form a stonelike mass. Portland cement typically makes up about 15 percent of the PCC mixture by weight. Portland cement is manufactured by crushing, milling, and blending selected raw materials containing appropriate proportions of lime, iron, silica, and alumina. Most Portland cement particles are less than 0.045 mm (No. 325 sieve) in diameter.
Portland cement combined with water forms the cement paste component of the concrete mixture. The paste normally constitutes about 25 to 40 percent of the total volume of the concrete. Air is also a component of the cement paste, occupying from 1 to 3 percent of the total concrete volume, up to 8 percent (5 to 8 percent typical) in air entrained concrete. In terms of absolute volume, the cementing materials make up between about 7 and 15 percent of the mix, and water makes up 14 to 21 percent.
Supplementary cementitious materials are sometimes used to modify or enhance cement or concrete properties. They typically include pozzolanic or self-cementing materials. Pozzolanic materials are materials comprised of amorphous siliceous or siliceous and aluminous material in a finely divided (powdery) form, similar in size to Portland cement particles, that will, in the presence of water, react with an activator, typically calcium hydroxide and alkalis, to form compounds possessing cementitious properties. Descriptions of various kinds of pozzolans and their specifications are provided in ASTM C618. Self-cementing materials are materials that react with water to form hydration products without any activator.
Supplementary cementitious materials can affect the workability, heat released during hydration, the rate of strength gain, the pore structure, and the permeability of the hardened cement paste.
Coal fly ash that is produced during the combustion of bituminous coals exhibits pozzolanic properties. Silica fume is also a pozzolanic material consisting almost entirely (85 percent or more) of very fine particles (100 times smaller than Portland cement) that are highly reactive.
Coal fly ash produced during the combustion of subbituminous coal exhibits self-cementing properties (no additional activators, such as calcium hydroxide, are needed). Similarly, ground granulated blast furnace slag reacts with water to form hydration products that provide the slag with cementitious properties.
Coal fly ash and ground granulated blast furnace slag can be blended with Portland cement prior to concrete production or added separately to a concrete mix (admixture). Silica fume is used exclusively as an admixture.
Chemical and Mineral Admixtures
An admixture is a material, other than Portland cement, water and aggregate, that is used in concrete as it is mixed to modify the fresh or hardened concrete properties. Chemical admixtures fall into three basic categories. They include water-reducing agents, air-entraining agents, and setting agents. Chemical admixtures for concrete are described in ASTM C494.
Water-reducing agents are chemicals that are used to reduce the quantity of water that needs to be added to the mix, at the same time producing equivalent or improved workability and strength.
Air entrainment increases the resistance of concrete to disintegration when exposed to freezing and thawing, increases resistance to scaling (surface disintegration) that results from deicing chemicals, increases resistance to sulfate attack, and reduces permeability. Air entrainment can be accomplished by adding an air-entraining admixture during mixing. There are numerous commercial air entraining admixtures manufactured. Descriptions and specifications are described in ASTM C260.
Setting agents can be used to either retard or accelerate the rate of setting of the concrete. Retarders are sometimes used to offset the accelerating effect of hot weather or to delay the set when placing of the concrete may be difficult. Accelerators are used when it is desirable to gain strength as soon as possible to support design loads. Calcium chloride is an active material that is most commonly used as an accelerator. Setting agents (retarders and accelerators) are described in greater detail in ASTM C494.
MATERIAL PROPERTIES AND TESTING METHODS
Concrete Aggregate
Since aggregates used in concrete mixtures comprise approximately 80 to 85 percent of the concrete mixture by mass (60 to 75 percent of the concrete mixture by volume), the aggregate materials used have a profound influence on the properties and performance of the mixture in both the plastic and hardened states. The following is a listing and brief comment on some of the more important properties for aggregates that are used in concrete paving mixtures:
- Gradation – the size distribution of the aggregate particles affects the relative proportions, cementing materials and water requirements, workability, pumpability, economy, porosity, shrinkage, and durability. The size distribution of the aggregate particles should be a combination of sizes that results in a minimum of void spaces.
- Absorption – the absorption and surface moisture condition of aggregates must be determined so that the net water content of the concrete can be controlled.
- Particle Shape and Surface Texture – the particle shape and surface texture of both coarse and fine aggregates have a significant influence on the properties of the plastic concrete. Rough textured, angular, or elongated particles require more water to produce workable concrete than smooth, rounded, compact aggregates, and as a result, these aggregates require more cementing materials to maintain the same water-cement ratio. Angular or poorly graded aggregates may result in the production of concrete that is more difficult to pump and also may be more difficult to finish. The hardened concrete strength will generally increase with increasing coarse aggregate angularity, and flat or elongated coarse aggregate particles should be avoided Rounded fine aggregate particles are more desirable because of their positive effect on plastic concrete workability.
- Abrasion Resistance – the abrasion resistance of an aggregate is often used as a general index of its quality.
- Durability – resistance to freezing and thawing is necessary for concrete aggregates, and is related to the aggregate porosity, absorption, permeability, and pore structure.
- Deleterious Materials – aggregates should be free of potentially deleterious materials such as clay lumps, shales, or other friable particles, and other materials that could affect its chemical stability, weathering resistance, or volumetric stability.
- Particle Strength – for normal concrete pavements, aggregate strength is rarely tested. It is usually much greater than and therefore not as critical a parameter as the paste strength or the paste-aggregate bond. Particle strength is an important factor in high-strength concrete mixtures.
Table 24-5 provides a list of standard test methods that are used to assess the suitability of conventional mineral aggregates in Portland cement concrete paving applications.
Table 24-5. Concrete aggregate test procedures.
Property |
Test Method |
Reference |
General Specifications |
Concrete Aggregates |
ASTM C33 |
Ready Mixed Concrete |
ASTM C94/ AASHTO M157M |
Concrete Made by Volumetric Batching and Continuous Mixing |
ASTM C685/AASHTO M241 |
Terminology Related to Concrete and Concrete Aggregates |
ASTM C125 |
Gradation |
Sizes of Aggregate for Road and Bridge Construction |
ASTM D448/AASHTO M43 |
Sieve Analysis of Fine and Coarse Aggregate |
ASTM C136/AASHTO T27 |
Absorption |
Specific Gravity and Absorption of Coarse Aggregate |
ASTM C127/AASHTO T85 |
Specific Gravity and Absorption of Fine Aggregate |
ASTM C128/AASHTO T84 |
Particle Shape and Surface Texture |
Flat and Elongated Particles in Coarse Aggregate |
ASTM D4791 |
Uncompacted Voids Content of Fine Aggregate
(As Influenced by Particle Shape, Surface Texture, and Grading) |
ASTM C1252/AASHTO TP33 |
Index of Aggregate Particle Shape and Texture |
ASTM D3398 |
Abrasion Resistance |
Resistance to Degradation of Large-Size Coarse Aggregate by Abrasion and Impact in the Los Angeles Machine |
ASTM C535 |
Resistance to Degradation of Small-Size Coarse Aggregate by Abrasion and Impact in the Los Angeles Machine |
ASTM C131/AASHTO T96 |
Durability |
Aggregate Durability Index |
ASTM D3744/AASHTO T210 |
Soundness of Aggregates by Use of Sodium Sulfate or Magnesium Sulfate |
ASTM C88/AASHTO T104 |
Soundness of Aggregates by Freezing and Thawing |
AASHTO T103 |
Deleterious Components |
Petrographic Examination of Aggregates for Concrete |
ASTM C295 |
Organic Impurities in Fine Aggregate for Concrete |
ASTM C40 |
Clay Lumps and Friable Particles in Aggregates |
ASTM C142 |
Plastic Fines in Graded Aggregates and Soils by Use of the Sand Equivalent Test |
ASTM D2419 |
Volume Stability |
Potential Volume Change of Cement-Aggregate Combinations |
ASTM C342 |
Accelerated Detection of Potentially Deleterious Expansion of Mortar Bars Due to Alkali-Silica Reaction |
ASTM C227 |
Portland Cement and Supplementary Cementitious Materials
Although it comprises between only 7 to 15 percent of the absolute volume of concrete mixture, it is the hardened paste that is formed by hydration of the cement upon the addition of water that binds the aggregate particles together to form a stonelike mass. Hence, the properties of the concrete in the plastic and hardened state are greatly influenced by the properties of the cementing material, which can consist of Portland cement alone or blends of Portland cement with supplementary cementitious materials. Some of the more important properties of the cement binder include:
- Chemical Composition – differences in chemical composition, particularly with supplementary cementitious materials that could be less uniform than Portland cement, could affect early and ultimate strengths, heat released, setting time, and resistance to deleterious materials.
- Fineness – the fineness of the cement or supplementary cementitious materials affects heat release and rate of hydration. Finer materials react faster, with a corresponding increase in early strength development, primarily during the first 7 days. Fineness also influences workability, since the finer the material, the greater the surface area and frictional resistance of the plastic concrete.
- Soundness – refers to the ability of the cement paste to retain its volume after setting, and is related to the presence of excessive amounts of free lime or magnesia in the cement or supplementary cementitious material.
- Setting Time – the setting time for the cement paste is an indication of the rate at which hydration reactions are occurring and strength is developing and can be used as an indicator as to whether or not the paste is undergoing normal hydration reactions.
- False Set – false set or early stiffening of the cement paste is indicated by a significant loss of plasticity without the evolution of heat shortly after the concrete is mixed.
- Compressive Strength – compressive strength is influenced by cement composition and fineness. Compressive strengths for different cements or cement blends are established by compressive strength testing of mortar cubes prepared using a standard graded sand.
- Specific Gravity – specific gravity is not an indication of the quality of the cement, but is required for concrete mix design calculations. The specific gravity of Portland cement is approximately 3.15.
Table 24-6 provides a list of standard laboratory tests that are presently used to evaluate the mix design or expected performance of Portland cement and supplementary cementitious materials for use in concrete paving mixtures.
Table 24-6. Portland cement and supplementary cementitious materials test procedures.
Property |
Test Method |
Reference |
General Specifications |
Portland Cement |
ASTM C150 |
Blended Hydraulic Cement |
ASTM C595 |
Expansive Hydraulic Cement |
ASTM C845 |
Pozzolan Use as a Mineral Admixture |
ASTM C618 |
Ground Blast Furnace Slag Specifications |
ASTM C989 |
Silica Fume Specifications |
ASTM C1240 |
Chemical Composition |
Chemical Analysis of Hydraulic Cements |
ASTM C114 |
Fineness |
Fineness of Hydraulic Cement by the 150 µm (No. 100) and 75 µm (No. 200) Sieves |
ASTM C184/AASHTO 128 |
Fineness of Hydraulic Cement and Raw Materials by the 300 µm (No. 50), 150 µm (No. 100) and 75 µm (No. 200) Sieves by Wet Methods |
ASTM C786 |
Fineness of Hydraulic Cement by the 45 µm (No. 325) Sieve |
ASTM C430/AASHTO T192 |
Fineness of Portland Cement by Air Permeability Apparatus |
ASTM C204/AASHTO T153 |
Fineness of Portland Cement by the Turbidimeter |
ASTM C115/AASHTO T98 |
Cement Soundness |
Autoclave Expansion of Portland Cement |
ASTM C151/AASHTO T107 |
Setting Time |
Time of Setting of Hydraulic Cement by Vicat Needle |
ASTM C191/AASHTO T131 |
Time of Setting of Hydraulic Cement by Gillmore Needles |
ASTM C266/AASHTO T154 |
Time of Setting of Hydraulic Cement Mortar by Modified Vicat Needle |
ASTM C807 |
False Set |
Early Stiffening of Portland Cement (Mortar Method) |
ASTM C359/AASHTO T185 |
Early Stiffening of Portland Cement
(Paste Method) |
ASTM C451/AASHTO T186 |
CONCRETE PAVING MATERIAL
The mix proportions for concrete paving mixtures are determined in the laboratory during mix design testing. This involves determination of the optimum characteristics of the mix in both the plastic and hardened states to ensure that the mix can be properly placed and consolidated, finished to the required texture and smoothness, and will have the desired properties necessary for pavement performance. Properly designed, placed, and cured concrete paving mixtures should be evaluated for the following properties:
Freshly Mixed (Plastic) Concrete
- Slump – slump is an indication of the relative consistency of the plastic concrete. Concrete of plastic consistency does not crumble but flows sluggishly without segregation.
- Workability – workability is a measure of the ease of placing, consolidating, and finishing freshly mixed concrete. Concrete should be workable but not segregate or bleed excessively.
- Setting Time – knowledge of the rate of reaction between cementing materials and water (hydration) is important to determine setting time and hardening. The setting times of concrete mixtures do not correlate directly with the setting times of the cement paste because of water loss and temperature differences.
- Air Content – the amount of entrapped or entrained air in the plastic concrete can influence the workability of the concrete mixture and reduce its propensity for bleeding.
Hardened Concrete
- Strength – concrete pavements must have adequate flexural strength to support the design traffic loads (repetitions of loaded axles) that will be applied over the service life of the facility. While compressive strength can also be measured, flexural strength is more relevant to the design and performance of concrete pavements.
- Density – the density of concrete paving mixes varies depending on the amount and relative density of the aggregate, the amount of air that is entrained or entrapped, and the water and cementing materials content of the concrete.
- Durability – the hardened concrete pavement must be able to resist damage from freezing and thawing, wetting and drying, and chemical attack (e.g., from chlorides or sulfates in deicing salts).
- Air Content – the finished and cured concrete should have adequate entrained air in the hardened cement paste to be able to withstand cycles of freezing and thawing.
- Frictional Resistance – for user safety, the surface of an exposed concrete pavement must provide adequate frictional resistance and resist polishing under traffic. Frictional resistance is a function of the aggregates used and the compressive strength of the concrete.
- Volume Stability – concrete paving mixtures must be volumetrically stable and must not expand due to alkali aggregate reactivity. Concrete paving mixtures should not shrink excessively upon drying.
Table 24-7 provides a list of standard laboratory tests that are presently used to evaluate the mix design or expected performance of concrete paving mixtures.
Table 24-7. Concrete paving materials test procedures.
Property |
Test Method |
Reference |
General Specifications |
Ready Mixed Concrete |
ASTM C94/AASHTO M157 |
Concrete Made by Volumetric Batching and Continuous Mixing |
ASTM C685/AASHTO M241 |
Concrete Aggregates |
ASTM C33 |
Terminology Related to Concrete and Concrete Aggregates |
ASTM C125 |
Pozzolan Use as a Mineral Admixture |
ASTM C618 |
Ground Blast Furnace Slag Specifications |
ASTM C989 |
Chemical Admixtures for Concrete |
ASTM C494 |
Air Entraining Agents |
ASTM C260 |
Silica Fume Specifications |
ASTM C1240 |
Slump |
Slump of Hydraulic Cement Concrete |
ASTM C143/AASHTO T119 |
Workability |
Bleeding of Concrete |
ASTM C232/AASHTO T158 |
Hydration and Setting |
Time of Setting of Concrete Mixtures by Penetration Resistance |
ASTM C403 |
Strength |
Compressive Strength of Cylindrical Concrete Specimens |
ASTM C39/ASHTO T22 |
Flexural Strength of Concrete
(Using Simple Beam with Third-Point Loading) |
ASTM C78/ AASHTO T96 |
Splitting Tensile Strength of Cylindrical Concrete Specimens |
ASTM C496/AASHTO T198 |
Air Content |
Microscopical Determination of Parameters of the Air-Void System in Hardened Concrete |
ASTM C457 |
Air Content of Freshly Mixed Concrete by the Pressure Method |
ASTM C231/AASHTO T152 |
Air Content of Freshly Mixed Concrete by the Volumetric Method |
ASTM C173/AASHTO T196 |
Unit Weight, Yield, and Air Content of Concrete |
ASTM C138 |
Density |
Specific Gravity, Absorption, and Voids in Hardened Concrete |
ASTM C642 |
Durability |
Resistance of Concrete to Rapid Freezing and Thawing |
ASTM C666 |
Scaling Resistance of Concrete Surfaces Exposed to Deicing Chemicals |
ASTM C131/AASHTO T96 |
Volume Stability |
Length Change of Hardened Hydraulic-Cement Mortar and Concrete |
ASTM C157 |
Length Change of Concrete Due to Alkali-Carbonate Rock Reaction |
ASTM C1105 |
REFERENCES FOR ADDITIONAL INFORMATION
ACI Manual of Concrete Practice, Part 1 - Materials and General Properties of Concrete. American Concrete Institute, Detroit, Michigan, 1994.
Kosmatka, S. H. and W. C. Panarese. Design and Control of Concrete Mixtures. Portland Cement Association, Skokie, Illinois, 1995.
Neville, A. M. Properties of Concrete, Fourth Edition. John Wiley & Sons, New York, New York, 1996.
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