Analytical Study of Effects of Truck Tire Pressure on Pavements with Measured Tire–Pavement Contact Stress Data

2005 ◽  
Vol 1919 (1) ◽  
pp. 111-120 ◽  
Author(s):  
Randy B. Machemehl ◽  
Feng Wang ◽  
Jorge A. Prozzi
Keyword(s):  
Conventional Method ◽  
Contact Stress ◽  
Asphalt Concrete ◽  
Pressure Effects ◽  
Tire Pressure ◽  
Variance Model ◽  
Truck Tire ◽  
Concrete Layer ◽  
Pavement Structures ◽  
Asphalt Concrete Pavement

Truck tire inflation pressure plays an important role in the tire–pavement interaction process. As a conventional approximation method in many pavement studies, tire–pavement contact stress is frequently assumed to be uniformly distributed over a circular contact area and to be simply equal to the tire pressure. However, recent studies have demonstrated that the tire–pavement contact stress is far from uniformly distributed. Measured tire–pavement contact stress data were input into an elastic multilayer pavement analysis program to compute pavement immediate responses. Two asphalt concrete pavement structures, a thick pavement and a thin pavement, were investigated. Major pavement responses at locations in the pavement structures were computed with the measured tire–pavement contact stress data and were compared with the conventional method. The computation results showed that the conventional method tends to underestimate pavement responses at low tire pressures and to overestimate pavement responses at high tire pressures. A two-way analysis of variance model was used to compare the pavement responses to identify the effects of truck tire pressure on immediate pavement responses. Statistical analysis found that tire pressure was significantly related to tensile strains at the bottom of the asphalt concrete layer and stresses near the pavement surface for both the thick and thin pavement structures. However, tire pressure effects on vertical strain at the top of the subgrade were minor, especially in the thick pavement.

Field Investigation into Effects of Vehicle Speed and Tire Pressure on Asphalt Concrete Pavement Strains

1996 ◽  
Vol 1539 (1) ◽  
pp. 66-71 ◽  
Author(s):  
Karim Chatti ◽  
Hyung B. Kim ◽  
Kyong K. Yun ◽  
Joe P. Mahoney ◽  
Carl L. Monismith
Keyword(s):  
Asphalt Concrete ◽  
Pressure Effect ◽  
Field Investigation ◽  
Vehicle Speed ◽  
Tire Pressure ◽  
Mount Vernon ◽  
Concrete Layer ◽  
Speed Effect ◽  
Longitudinal Strains ◽  
Percent Decrease

An asphalt concrete section on a test track in the PACCAR Technical Center in Mount Vernon, Washington, was fitted with strain gauges at the surface and in pavement cores and tested using an instrumented truck operated at different speeds and with different tire pressures. The field test results are presented. The results indicate that the effects of both vehicle speed and tire pressure–contact area on pavement strains are significant: increasing vehicle speed from 2.7 km/hr (1.7 mi/hr) to 64 km/hr (40 mi/hr) caused a decrease of approximately 30 to 40 percent in longitudinal strains at the bottom of the asphalt concrete layer, which was 137 mm (5.4 in.) thick. The speed effect on transverse strains is lower, causing only a 15 to 30 percent decrease. Reducing tire pressure from 620 kPa (90 psi) to 214 kPa (30 psi) caused a decrease of approximately 20 to 45 percent in the horizontal strains at the bottom of the asphalt concrete layer. The pressure effect on surface strains was significantly lower, causing only a 5 to 20 percent decrease. The speed effect was somewhat reduced at lower pressures, and the pressure effect was reduced at higher speeds.

Permeability of Asphalt Surface Seals and Their Effect on Aging of Underlying Asphalt Concrete

1996 ◽  
Vol 1535 (1) ◽  
pp. 124-130 ◽  
Author(s):  
Joe W. Button
Keyword(s):  
Asphalt Concrete ◽  
Concrete Slab ◽  
Heat Exposure ◽  
Concrete Pavement ◽  
Oxidative Aging ◽  
Actinic Light ◽  
Concrete Layer ◽  
Uppermost Layer ◽  
Asphalt Concrete Pavement ◽  
Slurry Seal

Asphalt surface seals are defined as slurry seals, micro-surfacings, and chip seals (seal coats). The relative aging abatement effects of surface seals on the upper 13 mm (½ in.) of an asphalt pavement were estimated. A laboratory aging experiment was devised wherein a surface seal was simulated by a membrane that could be easily removed after the artificial aging process without affecting the uppermost layer of asphalt in the asphalt concrete. By comparing laboratory aging data with existing field data on aged asphalt pavements it was possible to make inferences about the number of years an asphalt surface seal will delay hardening of an underlying asphalt concrete layer. Compacted asphalt concrete slab specimens (40 × 60 × 13 mm) were prepared in the laboratory. Half of each slab was covered with an impermeable membrane; then the specimens were exposed to hot air to accelerate oxidative aging. Following the heat exposure, asphalt was extracted and physical and chemical tests were performed to measure hardening of the covered and uncovered specimens. Permeabilities of laboratory prepared slurry seal, micro-surfacing, and seal coat specimens were measured. By knowing the amount of oxidative aging that occurred in uncovered and covered specimens of asphalt concrete and the permeability of the surface seals, the effects of the surface seals on aging of an underlying asphalt concrete layer were interpolated. Testing indicated that a surface seal can retard oxidative hardening of an underlying asphalt concrete layer by 0 to 2 years, depending on the situation. However, most of the oxidative aging in the upper stratum of an asphalt concrete pavement occurs during the first 4 years after construction. After this period, the asphalt aging rate decreases significantly. Therefore, for a surface seal to significantly delay oxidative hardening of the underlying pavement, it must be placed during the first 2 years (approximately) of the pavement's life. It was demonstrated that ultraviolet (actinic) light penetrates asphalt cement only a few microns and, therefore, does not contribute materially to hardening of the uppermost 13 mm of an asphalt concrete pavement. Permeability of a slurry seal or micro-surfacing after sufficient traffic to effect maximum compaction is less than 1 × 10−5 cm/sec. Permeability to water and air of an asphalt seal coat (chip seal) is essentially zero. For practical purposes, these three surface seals will protect the top 13 mm of an underlying pavement from oxidation as if they were impermeable to air and water.

Experience of application of epoxн asphalt concrete pavement on road bridges

2019 ◽  
pp. 78-92
Author(s):  
Vladimir Zelenovsky ◽  
◽  
Ivan Kopinets ◽  
Arthur Onishchenko ◽  
◽  
...  
Keyword(s):  
Asphalt Concrete ◽  
Concrete Pavement ◽  
Asphalt Concrete Pavement

Thermomechanical Coupling of a Hyper-viscoelastic Truck Tire and a Pavement Layer and its Impact on Three-dimensional Contact Stresses

2021 ◽  
pp. 036119812110171
Author(s):  
Angeli Jayme ◽  
Imad L. Al-Qadi
Keyword(s):  
Contact Stress ◽  
Contact Area ◽  
Three Dimensional ◽  
Interaction Model ◽  
Rolling Resistance ◽  
Contact Stresses ◽  
Thermomechanical Coupling ◽  
Temperature Profiles ◽  
Near Surface ◽  
Truck Tire

A thermomechanical coupling between a hyper-viscoelastic tire and a representative pavement layer was conducted to assess the effect of various temperature profiles on the mechanical behavior of a rolling truck tire. The two deformable bodies, namely the tire and pavement layer, were subjected to steady-state-uniform and non-uniform temperature profiles to identify the significance of considering temperature as a variable in contact-stress prediction. A myriad of ambient, internal air, and pavement-surface conditions were simulated, along with combinations of applied tire load, tire-inflation pressure, and traveling speed. Analogous to winter, the low temperature profiles induced a smaller tire-pavement contact area that resulted in stress localization. On the other hand, under high temperature conditions during the summer, higher tire deformation resulted in lower contact-stress magnitudes owing to an increase in the tire-pavement contact area. In both conditions, vertical and longitudinal contact stresses are impacted, while transverse contact stresses are relatively less affected. This behavior, however, may change under a non-free-rolling condition, such as braking, accelerating, and cornering. By incorporating temperature into the tire-pavement interaction model, changes in the magnitude and distribution of the three-dimensional contact stresses were manifested. This would have a direct implication on the rolling resistance and near-surface behavior of flexible pavements.

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