Perpetual Pavements

Advancements in milling, recycling and HMA technology over the last few decades have created HMA pavements that perform better, longer and with lower life-cycle costs than was previously possible.  Today’s HMA pavements can be designed to last in perpetuity.

A Perpetual Pavement is defined as an asphalt pavement designed and built to last longer than 50 years without requiring major structural rehabilitation or reconstruction, and needing only periodic surface renewal in response to distresses confined to the top of the pavement.  The concept of Perpetual Pavements, or long-lasting HMA pavements, is not new.  Full-depth and deep-strength HMA pavement structures have been constructed since the 1960s, and those that were well-designed and well-built have been very successful in providing long service lives under heavy traffic (APA, 2002).

Figure 1: I-90 Perpetual Pavement	Figure 2: I-90 Perpetual Pavement

The basic concept is that HMA pavements over a minimum strength are not likely to exhibit structural damage even when subjected to very high traffic flows over long periods of time.  Rather, deterioration seems to initiate in the pavement surface as either top-down cracking or rutting.  If surface-initiated cracking and rutting can be detected and remedied before they impact the structural integrity of the pavement, the pavement design life could be greatly increased.

Researchers have used this idea as well as pavement materials research to develop a basic perpetual pavement structural concept.  This concept uses a thick HMA pavement over a strong foundation design with three layers, each one tailored to resist specific stresses (TRB, 2001):

1. HMA base layer.  This is the bottom layer designed specifically to resist fatigue cracking.  Two approaches can be used to resist fatigue cracking in the base layer.  First, the total pavement thickness can be made great enough such that the tensile strain at the bottom of the base layer is insignificant.  Alternatively, the HMA base layer could be made using an extra-flexible HMA.  This can be most easily accomplished by increasing the asphalt content.  Combinations of these two approaches can also work.
2. Intermediate layer.  This is the middle layer designed specifically to carry most of the traffic load.  Therefore it must be stable (able to resist rutting) as well as durable.  Stability can best be provided by using stone-on-stone contact in the coarse aggregate and using a binder with the appropriate high-temperature grading.
3. Wearing surface.  This is the top layer designed specifically to resist surface-initiated distresses such as top-down cracking and rutting.  Other specific distresses of concern would depend upon local experience. 

In order to work, the above pavement structure must be built on a solid foundation.  Nunn (1998) notes that rutting on roads built on subgrade with a CBR greater than 5 percent originates almost solely in the HMA layers, which suggests that a subgrade with a CBR greater than 5 percent (resilient modulus greater than about 7,000 psi) should be considered adequate.  As always, proper construction techniques are essential to a perpetual pavement's performance. 

Finally, the most important point in this brief perpetual pavement discussion is that it is possible to design and build HMA pavements with extremely long design lives.  In fact, some HMA pavements in service today are living examples of perpetual pavements. 

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