Early-Life, Long-Term, and Seasonal Variations in Skid Resistance in Flexible and Rigid Pavements

Skidding contributes to up to 35% of wet weather accidents. Increased temperature and surface wear and polishing may affect the available friction and further increase skid-related accidents. Several studies have attempted to examine and quantify these variations mostly with inadequate or inappropriate conclusions. The surface friction of both port-land cement concrete (PCC) and asphalt concrete (AC) pavements was measured monthly to determine the influencing factors and quantify the seasonal fluctuation. Skid number (SN) and pertinent data of the Long-Term Pavement Performance program were obtained for both PCC and AC pavements, incorporating all geographic and climatic regions of the United States and Canada, to determine the contributing factors and quantify the long-term and early-life variations of surface friction. Surface friction was shown to fluctuate as a result of ambient or pavement temperature fluctuation at 0.35 British pendulum number per 1°C change in temperature. The effect of prior weather was shown to be insignificant. Following the construction, AC and PCC surface friction was shown to increase by 5 SN in about 18 months and 4 SN in about 2½ years. Skid resistance was shown to decrease thereafter at 0.27 SN for AC and at 0.24 SN for PCC pavements per million vehicle passes. Cumulative traffic passes, pavement age, speed, and temperature during the testing and PCC pavement surface texture types were found to be statistically significant for the prediction of long-term surface friction. AC pavement long-term surface friction was shown to be more sensitive, as compared with PCC, to predominant climatic condition.

[1]  Thomas H. Wenzel,et al.  Crash Experience on Tined and Continuously Ground Portland Cement Concrete Pavements , 1998 .

[2]  Susan L. Tighe,et al.  Pavement Surface Mixture, Texture and Skid Resistance: A Factorial Analysis , 2008 .

[3]  J J Emery,et al.  Skid Resistance Predictive Models for Asphaltic Concrete Surface Courses , 1982 .

[4]  Rolands L. Rizenbergs,et al.  Relation of accidents and pavement friction on rural, two-lane roads , 1977 .

[5]  K J Kercher,et al.  Seasonal variation in skid resistance of bituminous surfaces in Indiana , 1980 .

[6]  Josué M. Yambó,et al.  INCORPORATING ROAD SAFETY INTO PAVEMENT MANAGEMENT: MAXIMIZING ASPHALT PAVEMENT SURFACE FRICTION FOR ROAD SAFETY IMPROVEMENTS , 2005 .

[7]  G. M. Davis The Department of Transportation , 1970 .

[8]  I C Butler,et al.  Measurement of Skidding Resistance and Surface Texture and the Use of Results in the United Kingdom , 1990 .

[9]  Kazuo Saito,et al.  MECHANISTIC MODEL FOR PREDICTING SEASONAL VARIATIONS IN SKID RESISTANCE , 1983 .

[10]  Robert V. Brill,et al.  Applied Statistics and Probability for Engineers , 2004, Technometrics.

[11]  Wenbing Song,et al.  Investigation of Skid Resistance of Hot-Mix-Asphalt-Surfaced Pavements in Maryland State Highway Network System , 2006 .

[12]  Melvin Alexander Applied Statistics and Probability for Engineers , 1995 .

[13]  T E Hoerner,et al.  HIGH PERFORMANCE CONCRETE PAVEMENT: PAVEMENT TEXTURING AND TIRE-PAVEMENT NOISE , 2002 .

[14]  J R Hosking,et al.  Relationship between skidding resistance and accident frequency: estimates based on seasonal variation , 1986 .

[15]  John J. Henry,et al.  SHORT-TERM, WEATHER-RELATED SKID RESISTANCE VARIATIONS , 1981 .

[16]  Michael J Grady What's all the noise about? , 2006 .

[17]  Susan L. Tighe,et al.  Statistical Modeling in Pavement Management , 2008 .

[18]  Farhad Reza,et al.  Changes in Asphalt Pavement Friction Components and Adjustment of Skid Number for Temperature , 2005 .

[19]  P. Jayawickrama,et al.  Correction of Field Skid Measurements for Seasonal Variations in Texas , 1998 .