Abstract
In the Pacific Northwest, forest roads have the potential to cause significant environmental degradation, especially to water resources due to increased sediment production. The goal of this research is to improve the understanding of road degradation during hauling by improving our understanding of the aggregate degradation process. We correlate the wear rates to standard material property tests that may allow for improved prediction of the impacts from forest roads based on the selection of aggregate surfacing. Finally, we determine the changes in stress distribution between the subgrade and aggregate interface. High-, medium-, and low-quality aggregates were used from three quarries in western Oregon for this project. These aggregates are indicative of the range of materials used on forest roads in the region. Two material property tests, namely the Los Angeles (LA) abrasion and micro-Deval tests, were used to determine their ability to predict aggregate performance during hauling by relating values for aggregate wear to these aggregate properties. Eighteen nonwoven geotextile bags were created, measuring 60 cm (two-feet long) and 20 cm (eight inches) in diameter, with a pore size equivalent to a 0.149 mm (# 100) sieve. They were filled with a known quantity and particle size distribution of aggregate and embedded into a newly constructed forest road. Stress gages were installed in the road surface between the aggregate and subgrade levels to record the changes in stress at the subgrade level. Samples were subjected to three levels of traffic (500, 950, and 1500 passes) using a loaded dump-truck that had a steering axle and one tandem drive axle, weighing 25,038 kg or 55,200 lb. The results showed that less breakage occurred with the medium- and high-quality aggregates than the low-quality aggregate. There was a correlation between the material property test (either the micro-Deval or the LA abrasion test) and the fine index, indicating the predictability of these tests in terms of aggregate performance. Finally, the higher quality aggregate was able to better distribute the stresses from the wheel better than the lower quality aggregate and was able to reduce the stress reaching the subgrade. Although the results are limited to the three types of rock used in this study, they indicate the ability of the high-quality aggregate to lessen the environmental impacts from forest roads.
Highlights
Forest roads serve multiple purposes, from providing access for recreation to facilitating the transport of timber products
The results show that the gradation curves for all three aggregates have a similar shape, and trend towards the theoretical maximum density (TMD) line after hauling occurred
A similar pattern appeared with the medium-quality rock, this was removed for clarity of display
Summary
Forest roads serve multiple purposes, from providing access for recreation to facilitating the transport of timber products. Many of these roads are designed with an aggregate surface to allow all-season use, which is necessary in the coastal forest of the Pacific Northwest in North America due to the likelihood of rain during much of the year. If these stresses exceed the bearing strength in the subgrade this can result in ruts that increase sediment production from the forest roads [1]. The reduction in subgrade stresses is vital, as most forest roads in the region do not control subgrade compaction during construction, resulting in weak subgrade or highly variable subgrade strength [2]. A reduction of one inch of surface aggregate on a forest road could save over $3542 per km ($5700 per mile)
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