Aggregate

Aggregate” is a collective term for the mineral materials such as sand, gravel and crushed stone that are used with a binding medium (such as water, bitumen, portland cement, lime, etc.) to form compound materials (such as asphalt concrete and portland cement concrete). By volume, aggregate generally accounts for 92 to 96 percent of HMA and about 70 to 80 percent of portland cement concrete. Aggregate is also used for base and subbase courses for both flexible and rigid pavements.

Aggregates can either be natural or manufactured. Natural aggregates are generally extracted from larger rock formations through an open excavation (quarry). Extracted rock is typically reduced to usable sizes by mechanical crushing. Manufactured aggregate is often the byproduct of other manufacturing industries.

This section will briefly discuss aggregate sources and quarrying operations then describe the basic aggregate mineral, chemical and physical properties most important to pavements and the typical tests used to determine these properties. The following source contains more detailed information on aggregate:

Aggregate Sources

Aggregates can come from either natural or manufactured sources. Natural aggregates come from rock, of which there are three broad geological classifications (Roberts, et al., 1996):

Igneous rock
These rocks are primarily crystalline and are formed by the cooling of molten rock material beneath the earth’s crust (magma).
Sedimentary rocks
These rocks are formed from deposited insoluble material (e.g., the remains of existing rock deposited on the bottom of an ocean or lake). This material is transformed to rock by heat and pressure. Sedimentary rocks are layered in appearance and are further classified based on their predominant mineral as calcareous (limestone, chalk, etc.), siliceous (chert, sandstone, etc.) or argillaceous (shale, etc.).
Metamorphic rock
These are igneous or sedimentary rocks that have been subjected to heat and/or pressure great enough to change their mineral structure so as to be different from the original rock.

Manufactured rock typically consists of industrial byproducts such as slag (byproduct of the metallurgical processing – typically produced from processing steel, tin and copper) or specialty rock that is produced to have a particular physical characteristic not found in natural rock (such as the low density of lightweight aggregate).

Aggregate Production

Aggregates are produced in a quarry or mine (Figure 1) whose basic function is to convert in situ rock into aggregate with specified characteristics. Usually the rock is blasted or dug from the quarry walls then reduced in size using a series of screens and crushers. Some quarries are also capable of washing the finished aggregate.

Aggregate mine
Figure 1. Aggregate mine.

 

Mineral Properties

An aggregate’s mineral composition largely determines its physical characteristics and how it behaves as a pavement material. Therefore, when selecting an aggregate source, knowledge of the quarry rock’s mineral properties can provide an excellent clue as to the suitability of the resulting aggregate. Cordon (1979) provides some general guidelines for aggregate used in HMA.

Table 1. Desirable Properties of Rocks for HMA
(from Cordon, 1979 as referenced in Roberts et al., 1996)

Rock Type Hardness, Toughness Resistance to Stripping1,2 Surface Texture Crushed Shape
Igneous
Granite Fair Fair Fair Fair
Syenite Good Fair Fair Fair
Diorite Good Fair Fair Good
Basalt (trap rock) Good Good Good Good
Diabase (trap rock) Good Good Good Good
Gabbro (trap rock) Good Good Good Good
Sedimentary
Limestone Poor Good Good Fair
Sandstone Fair Good Good Good
Chert Good Fair Poor Good
Shale Poor Poor Fair Fair
Metamorphic
Gneiss Fair Fair Good Good
Schist Fair Fair Good Fair
Slate Good Fair Fair Fair
Quartzite Good Fair Good Good
Marble Poor Good Fair Fair
Serpentine Good Fair Fair Fair
Notes:

  • Aggregates that are hydrophilic (water-loving) tend to strip more readily since water more easily replaces the asphalt film over each particle.

  • Freshly crushed aggregates with many broken ionic bonds tend to strip more easily.

In general, relationships between mineral and physical properties are quite complex, making it difficult to accurately predict how a particular aggregate source will behave based on mineral properties alone.

Chemical Properties

While relatively unimportant for loose aggregate, aggregate chemical properties are important in a pavement material. In HMA, aggregate surface chemistry can determine how well an asphalt cement binder will adhere to an aggregate surface. Poor adherence, commonly referred to as stripping, can cause premature structural failure. In PCC, aggregates containing reactive forms of silica can react expansively with the alkalis contained in the cement paste. This expansion can cause cracking, surface popouts and spalling. Note that some aggregate chemical properties can change over time, especially after the aggregate is crushed. A newly crushed aggregate may display a different affinity for water than the same aggregate that has been crushed and left in a stockpile for a year.

The following are typical chemical properties that are measured for aggregates:

Physical Properties

Aggregate physical properties are the most readily apparent aggregate properties and they also have the most direct effect on how an aggregate performs as either a pavement material constituent or by itself as a base or subbase material. Commonly measured physical aggregate properties are (Roberts et al., 1996):

These are not the only physical properties of aggregates but rather the most commonly measured. Tests used to quantify these properties are largely empirical. The physical properties of an aggregate can change over time. For instance, a newly crushed aggregate may contain more dust and thus be less receptive to binding with an asphalt binder

Aggregate as Base Material

Aggregate is often used by itself as an unbound base or subbase course. When used as such, aggregate is typically characterized by the preceding physical properties as well as overall layer stiffness. Layer stiffness is characterized by the same tests used to characterize subgrade stiffness.