Abstract
Pavement is an essential component of roads as it carries the traffic and provides the required riding comfort. Considering that numerous forest roads are approaching their end of life, the critical issue is identifying the best rational pavement design methods to reengineer existing and build new pavement structures. The purpose of this contribution was (1) to review the big development lines of pavement systems, (2) to have a critical look at the pavement engineering framework, and (3) to bring selected empirical design equations into a comparable scheme. The study resulted in the following significant findings. First, the Trésaguet and McAdam pavement systems represented the state of the art from the beginning of a formal forest road engineering discipline at the beginning of the 19th century and remained for almost 150 years. Second, the emergence of soil mechanics as a scientific discipline in the 1920s resulted in the optimal grading of aggregates and improvement of soils and aggregates with binders, such as lime, cement, and bitumen. Third, the rational pavement design consists of five essential components: (1) bearing resistance of the subsoil, (2) bearing resistance of the pavement structure, (3) lifecycle traffic volume, (4) uncertainties that amplify deterioration, and (5) the limit state criterion, defining thresholds, above which structural safety and serviceability are no longer met. Fourth, rational, formal pavement design approaches used for forest roads were »downsized« from methodologies developed for high-volume roads, among which the approaches of the American Association of State Highway and Transportation Officials (AASHTO) and US Army Corps of Engineers (USACE) are of primary interest. Fifth, the conversion of the AASHTO '93 and USACE '70 methods into the SI system indicated that both equations are sensitive to soil bearing resistance, measured in California Bearing Ratio (CBR). However, there is a lack of validation for the AASHTO and USACE equations for forest road conditions. Consequently, a factorial observational study to gain a basis for validation should be developed and implemented. Additionally, the conversion of simple soil bearing resistance measures, such as CBR, into the resilient modulus will be improved.
Highlights
Road networks are an essential part of our critical infrastructure systems, which provide essential services to move goods and people between origins and destinations
Low-volume roads have several definitions, Croat. j. for. eng. 42(2021)1 including that of the American Association of State Highway and Transportation Officials (AASHTO), which refers to a traffic volume from 10000 to 100,000 equivalent single axle loads (ESALs) over a road lifecycle (AASHTO 1993)
Almost 70 years have passed since the US Army Corps of Engineers (USACE) developed the first pavement design methods, and we are facing a whole set of pavement design approaches, which cover the entire range from empirical to purely analytical
Summary
Road networks are an essential part of our critical infrastructure systems, which provide essential services to move goods and people between origins and destinations. A former chairman of the Committee on LowVolume Roads (Coghlan 2000) estimated that low- volume roads carry only about 20% of the overall traffic. They include about 80% of the total length. 42(2021) including that of the American Association of State Highway and Transportation Officials (AASHTO), which refers to a traffic volume from 10000 to 100,000 equivalent single axle loads (ESALs) over a road lifecycle (AASHTO 1993). Assuming that about 50% of low-volume roads are urban, rural, and forest roads have a share in the overall road network length of about one third, which is incredible, considering that the relative value added flowing over this network is quite low.
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