Other featured projects

Highway Capacity Manual (HCM) Website

Integrated Transportation Information System (ITIS) Workshop

The ALERT Vehicle

The SUPERPAVE System

Demonstration Projects (DP)

DP-105 Advanced Transportation Management Technologies

DP-111 ITS/CVO Technology Truck

DP-112 Red Light Running Campaign

DP-115 Probabilistic Life Cycle Cost Analysis in Pavement Design

Test and Evaluation Projects (TE)

TE-29 Retroreflectivity

Application Projects (AP)

AP-101 Read Your Road

AP-101 Highway Safety Kiosk

| PROJECTS: DP-90 AND TE-39

The SUPERPAVE System
New Tools for Designing and Building More Durable Asphalt Pavements

Team Contacts:
John Bukowski or John D'Angelo or Thomas Harman


Pavements constructed of hot-mix asphalt are typically designed to last at least 20 years. Yet despite our best efforts, it is not uncommon to see severe rutting and cracking in asphalt pavements well before then, as environmental conditions and heavy traffic loading take their toll. The result: rougher rides, higher pavement maintenance and rehabilitation costs, and more work zones for motorists to negotiate.

The SUPERPAVE (SUperior PERforming Asphalt PAVEments) system was developed to give highway engineers and contractors the tools they need to design asphalt pavements that will perform better under extremes of temperature and heavy traffic loads.

The SUPERPAVE system was developed by the Strategic Highway Research Program (SHRP). The asphalt research program had three objectives:
  • To investigate why some pavements perform well, while others do not.
  • To develop tests and specifications for materials that will outperform and outlast the pavements being constructed today.
  • To work with highway agencies and industry to have the new specifications put to use.

After 5 years of intensive research and testing, SHRP introduced the SUPERPAVE system in 1992. The Federal Highway Administration then assumed responsibility for further development and validation of the SUPERPAVE specifications and test procedures and initiated a national program to encourage the adoption of the SUPERPAVE system.

Asphalt pavements account for more than 90 percent of all paved highways in the United States, and annual expenditures for asphalt pavements top $10 billion. If asphalt pavements can be designed to last longer, we stand to reap substantial benefits.

The SUPERPAVE system primarily addresses two pavement distresses: permanent deformation, which results from inadequate shear strength in the asphalt mix; and low-temperature cracking, which is generated when an asphalt pavement shrinks and the tensile stress exceeds the tensile strength.

The SUPERPAVE system consists of three interrelated elements:

  • Asphalt binder specification.
  • Volumetric mix design and analysis system.
  • Mix analysis tests and a performance prediction system that includes computer software, weather database, and environmental and performance models.

Taking the Guesswork Out of Binder Selection

Conventional viscosity and penetration tests for asphalt binders do not measure low-temperature properties. As a result, it can be difficult to select a binder that will work best under specific conditions. Two binders with the same viscosity grade might, for example, have the same consistency at the specified test temperature, but they might behave dramatically different at very low temperatures or at high pavement temperatures.

In contrast, the SUPERPAVE binder specification is a performance-based specification. It classifies binders into performance grades, based on a range of climates and pavement temperatures. The physical properties required for the binder are the same for all grades, but the temperature at which those properties must be attained is determined by the specific climatic conditions at the paving location. The specification applies to all unmodified binders and many modified binders.

SUPERPAVE binders are designated with a "PG" (performance grade) rating. The first number in the rating indicates the high-temperature grade; the second indicates the low-temperature grade. For example, a binder classified PG58-28 would meet the required physical properties at pavement temperatures as high as 58°C and as low as -28°C. The mix designer selects a SUPERPAVE binder based on the climate in which the pavement will serve and the traffic it will bear.

Three new tests are used to measure the physical properties of SUPERPAVE binders:

  • Dynamic shear test, which measures the binder's stiffness and phase angle at intermediate and high temperatures.
  • Bending beam test, which measures the low-temperature stiffness of the binder.
  • Direct tension test, which measures the low-temperature tensile and fracture properties.

The tests mimic actual environmental and traffic conditions at the project site. The results of the dynamic shear test indicate the binder's ability to withstand permanent deformation (which is often evidenced as rutting in the pavement) and fatigue cracking. The bending beam test results are used to predict low-temperature cracking problems. The results of the direct tension test provide additional information on how the binder will perform at low temperatures.


The SUPERPAVE Mix Design System

Steps to a SUPERPAVE Volumetric Mix Design
  • Select asphalt and aggregates that meet SUPERPAVE specifications.
  • Develop several aggregate trial blends to meet SUPERPAVE gradation requirements.
  • Blend asphalt with the trial blends and "age" the mixtures in an oven.
  • Compact the specimens and analyze the volumetrics of the trial blends.
  • Determine the optimum trial blend to serve as the design aggregate structure.
  • Compact samples of the design aggregate structure at differing amounts of asphalt binder and analyze the volumetrics to determine the design asphalt content.

The SUPERPAVE mix design system is based on volumetric proportioning of the asphalt and aggregate materials and laboratory compaction of trial mixes using the SUPERPAVE gyratory compactor.

The SUPERPAVE gyratory compactor is a transportable device whose primary function is to fabricate test specimens by simulating the effect of traffic on an asphalt pavement. The specimens fabricated with the gyratory compactor are used to determine the volumetric properties (air voids, voids in the mineral aggregate, and voids filled with asphalt) of SUPERPAVE mixes. Those properties, measured in the laboratory, indicate how well the mix will perform in the field. The gyratory compactor is also well-suited for quality control/ quality assurance, as it can be set up at the job site to verify that the delivered asphalt mix meets the job mix volumetric specifications.

By kneading mixes to simulate construction and traffic loads, the SUPERPAVE gyratory compactor provides specimens that are much more representative of actual in-service pavements. The level or amount of compaction is dependent on the environmental conditions and traffic levels expected at the job site.

To create a mix with a high degree of internal friction and thus a high shear strength, the SUPERPAVE mix design procedures include requirements for aggregate angularity and gradation. The design goal: a strong stone skeleton that will resist rutting, yet include enough asphalt and voids to improve the durability of the mix.


Predicting Pavement Performance

The SUPERPAVE system includes mix analysis procedures that predict how well a mix will perform in the field. These procedures are intended to provide additional information on asphalt mixes that will be placed in pavements with very high traffic volumes and loads. Two new, sophisticated pieces of laboratory equipment--the SUPERPAVE shear tester and the indirect tensile tester--are used to measure specific engineering properties of the laboratory-compacted asphalt mix. The test results are then entered into software models that predict how many equivalent single-axle loads the pavement will carry, or how much time will elapse, before a certain level of rutting, fatigue cracking, or low-temperature cracking develops.

The test procedures for the SUPERPAVE shear tester and the indirect tensile tester are currently being refined to ensure that the procedures are sound and that the results are repeatable. The performance prediction models are also undergoing evaluation and validation and will be refined as necessary.


Making It Happen--Partners in Implementation

Switching to the all-new SUPERPAVE system is a big task, necessitating careful planning and coordination among all the partners in the highway industry.

To insure that the switch to the SUPERPAVE system would be well planned and coordinated, the Federal Highway Administration (FHWA) established a national Asphalt Technical Working Group (TWG). Composed of representatives from highway agencies, suppliers, contractors, academia, and FHWA, the Asphalt TWG provides advice on how best to encourage the adoption of the SUPERPAVE system within the highway industry. Assisting the Asphalt TWG are several expert task groups composed of specialists in pertinent subject areas, such as binders, asphalt mixes, and pavement modeling.

The regional asphalt user-producer groups also play a key role in the SUPERPAVE implementation effort. Made up of highway agencies and companies that use and produce asphalt binders, the user-producer groups have outlined a sensible, planned strategy for adopting the SUPERPAVE system on a regional basis. They also provide a forum for discussing common concerns and arriving at workable solutions.

To bring the SUPERPAVE system and equipment closer to the users, five SUPERPAVE regional centers have been established. Under an FHWA program they will conduct a thorough and coordinated shakedown of the procedures used with the SUPERPAVE shear test and indirect tensile test. The centers, operated jointly by universities and State departments of transportation, will also provide training on a regional basis.



Getting Up to Speed

To help State highway agencies and contractors become proficient with the new SUPERPAVE procedures and devices, FHWA sponsors training courses in the use of the binder test equipment and mix equipment. The hands-on training is conducted at the National Asphalt Training Center, which FHWA established at the Asphalt Institute in Lexington, Kentucky.

During the first 18 months of SUPERPAVE training, the center held 30 courses in the SUPERPAVE binder and mix procedures and trained approximately 600 engineers and technicians. FHWA recently selected the Asphalt Institute to conduct the second phase of SUPERPAVE training. This phase will continue some of the early training courses, but will also develop training for more advanced mix analysis equipment. Training and assistance will be taken directly to the users and the regional centers.

In addition, under an FHWA contract, the University of Maryland and its project team are evaluating, validating, and refining the software and pavement performance models that form the core of the SUPERPAVE mix analysis and performance prediction procedures. Once the SUPERPAVE software is ready for release, the university will provide technical assistance and training workshops.

Not all training is conducted in the laboratory. FHWA's mobile asphalt laboratory brings technical assistance and training in the SUPERPAVE system directly to highway agencies and contractors at job sites around the country.

The American Association of State Highway and Transportation Officials (AASHTO) Subcommittee on Materials has reviewed and approved provisional standards for the SUPERPAVE binder and mix procedures. The standards have been published by AASHTO, so that engineers and technicians throughout the country can work from a common set of procedures and guidelines for the SUPERPAVE tests.


Timeline for SUPERPAVE

The Asphalt TWG has set a target date of 1997 for nation-wide implementation of the SUPERPAVE binder specification and 2000 for nationwide adoption of the SUPERPAVE volumetric mix design procedures. Most State highway agencies and many contractors already have the necessary binder test equipment and the SUPERPAVE gyratory compactor. Some States are already building SUPERPAVE pavements, and other projects are in the pipeline.


Better Roads Ahead

The SUPERPAVE system will mean major changes in the way we design asphalt mixes. It requires significant investments in equipment and training. But the extensive testing and validation conducted to date on the SUPERPAVE system indicate that SUPERPAVE pavements will last longer. Longer-lasting pavement will mean lower maintenance costs and fewer highway work zones. And that means better roads ahead.


SUPERPAVE Publications



For More Information

For more information about the SUPERPAVE System contact FHWA project managers John Bukowski, John D'Angelo, and Thomas Harman at:

John Bukowski
(202) 366-1287
FAX: (202) 366-7909
E-Mail: john.bukowski@fhwa.dot.gov

John D'Angelo
(202) 366-0121
FAX: (202) 366-7909
E-Mail: john.d'angelo@fhwa.dot.gov

Thomas Harman
(202) 366-0859
FAX: (202) 366-7909
E-Mail: thomas.harman@fhwa.dot.gov

U.S. Department of Transportation
Federal Highway Administration