Development of a model to predict pavement temperature for Alkufrah region in Libya

Preserving airport pavement means guarantying the safety operation of aircraft movements. There are four aspects that cause progressive pavement deterioration, i.e. the construction design and process, selected material, and maintenance management. One of the traffic aspects, jet engine exhaust, has not been discovered yet. The load pattern of the jet exhaust follows the schedule of aircraft traffic. The assumption held in this research is that the thermal load during aircraft movement may generate a high temperature, which is induced into pavement layers. The objective of this research is to determine the temperature gradient in the pavement, caused by the jet exhaust. This paper discusses the process of determining the temperature gradient in four stages, i.e. by carrying out the gap analysis, evaluation of pavement structures, determination of the load path and the magnitude, and defining the temperature gradient. The temperature gradient in the pavement layer is determined through the development of a model of cyclic loading. The thermal cyclic load follows the aircraft schedule pattern. The pavement temperature receives the thermal cyclic load of the sinusoid of solar radiation. The results indicate that the temperature of the pavement is increased and pavement temperature rises by 35 °C. However, after 60 seconds the remaining temperature of the pavement layer decreases to the initial temperature, which is caused by solar radiation.

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Modeling Pavement Temperature for Use in Binder Oxidation Models and Pavement Performance Prediction

Journal of Materials in Civil Engineering ◽

10.1061/(asce)mt.1943-5533.0000169 ◽

2011 ◽

Vol 23 (4) ◽

pp. 351-359 ◽

Cited By ~ 34

Author(s):

Rongbin Han ◽

Xin Jin ◽

Charles J. Glover

Keyword(s):

Performance Prediction ◽

Pavement Performance ◽

Pavement Temperature ◽

Binder Oxidation ◽

Pavement Performance Prediction

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Effect of Aging on Urban Asphalt Pavement

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.671-674.1287 ◽

2013 ◽

Vol 671-674 ◽

pp. 1287-1290

Author(s):

Ning Li Li ◽

Xin Po Zhao ◽

Chuang Du ◽

Cai Li Zhang ◽

Qing Yi Xiao

Keyword(s):

Softening Point ◽

Asphalt Pavement ◽

Early Years ◽

Service Period ◽

Viscosity Increase ◽

Pavement Temperature ◽

Years Of Service ◽

The City

The aging of asphalt pavement gets serious in the course of service due to the large number of vehicles and high pavement temperature. A survey was conducted on urban road’s asphalt pavement in the city of Tianjin. By analyzing the extracted asphalt sample from asphalt pavement built in different years, it shows that asphalt’s softening point and viscosity increase but its penetration and ductility attenuate with the extension of service period. Of which, the ductility changes dramatically with its ductility attenuating fast in the early years of service and the attenuation of ductility tending to slow down later. The vertical difference of aging in different depth of pavement is marked and degree of aging tends to attenuate from the surface to the center.

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Combating Urban Heat Island Effect—A Review of Reflective Pavements and Tree Shading Strategies

Buildings ◽

10.3390/buildings11030093 ◽

2021 ◽

Vol 11 (3) ◽

pp. 93

Author(s):

V. R. Sankar Cheela ◽

Michele John ◽

Wahidul Biswas ◽

Prabir Sarker

Keyword(s):

Urban Heat Island ◽

Urban Forest ◽

Critical Role ◽

Tree Canopy ◽

Mitigation Measures ◽

Heat Island ◽

Human Thermal Comfort ◽

Urban Heat ◽

Pavement Temperature ◽

Reflective Coatings

Pavements occupy about 40% of urban land cover, with 75–80% black top roads, playing a critical role in urban connectivity and mobility. Solar energy is absorbed and stored in pavements leading to an increase in surface temperatures. Decreasing green cover is further contributing to rise in regional temperatures. Due to this activity, the city experiences urban heat island (UHI). This study presents a critical review of the literature on mitigation measures to combat UHI using reflective pavements with an emphasis on durability properties and impacts of tree canopy. The strategies with a focus on application of chip seals, white toppings, and coatings were discussed. Role of surface reflectance, including those from asphalt and concrete pavements, albedo improvements, and technological trends, application of waste materials, and industrial by‐products are presented. Also, urban tree shading systems’ contribution to pavement temperature and microclimate systems is presented. The review shows that the development of mitigation measures using tree shading systems can reduce the pavement temperature during daytime and increase human thermal comfort. The outcomes of this review provide a scope for future studies to develop sustainable and state‐of‐the-art engineering solutions in the field of reflective coatings and urban forest systems.

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Modelling pavement temperature for winter maintenance operations

Canadian Journal of Civil Engineering ◽

10.1139/l03-107 ◽

2004 ◽

Vol 31 (2) ◽

pp. 369-378 ◽

Cited By ~ 8

Author(s):

Aly Sherif ◽

Yasser Hassan

Keyword(s):

Surface Temperature ◽

Air Temperature ◽

Negative Impact ◽

Weather Conditions ◽

Statistical Modelling ◽

Dew Point ◽

Road Maintenance ◽

Winter Maintenance ◽

Pavement Surface ◽

Pavement Temperature

Road and highway maintenance is vital for the safety of citizens and for enabling emergency and security services to perform their essential functions. Accumulation of snow and (or) ice on the pavement surface during the wintertime substantially increases the risk of road crashes and can have negative impact on the economy of the region. Recently, road maintenance engineers have used pavement surface temperature as a guide to the application of deicers. Stations for road weather information systems (RWIS) have been installed across Europe and North America to collect data that can be used to predict weather conditions such as air temperature. Modelling pavement surface temperature as a function of such weather conditions (air temperature, dew point, relative humidity, and wind speed) can provide an additional component that is essential for winter maintenance operations. This paper uses data collected by RWIS stations at the City of Ottawa to device a procedure that maximizes the use of a data batch containing complete, partially complete, and unusable data and to study the relationship between the pavement surface temperature and weather variables. Statistical models were developed, where stepwise regression was first applied to eliminate those variables whose estimated coefficients are not statistically significant. The remaining variables were further examined according to their contribution to the criterion of best fit and their physical relationships to each other to eliminate multicollinearities. The models were further corrected for the autocorrelation in their error structures. The final version of the developed models may then be used as a part of the decision-making process for winter maintenance operations.Key words: winter maintenance, pavement temperature, statistical modelling, RWIS.

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ROAD TEMPERATURE MODELLING WITHOUT IN-SITU SENSORS

The Baltic Journal of Road and Bridge Engineering ◽

10.3846/bjrbe.2017.30 ◽

2017 ◽

Vol 12 (4) ◽

pp. 241-247 ◽

Cited By ~ 1

Author(s):

Karol Opara ◽

Jan Zieliński

Keyword(s):

Energy Balance ◽

Urban Areas ◽

Initial Conditions ◽

Forecast Error ◽

Weather Data ◽

Forecast Errors ◽

The Road ◽

In Situ Sensors ◽

Pavement Temperature

Modelling of the pavement temperature facilitates winter road maintenance. It is used for predicting the glaze formation and for scheduling the spraying of the de-icing brine. The road weather is commonly forecasted by solving the energy balance equations. It requires setting the initial vertical profile of the pavement temperature, which is often obtained from the Road Weather Information Stations. The paper proposes the use of average air temperature from seven preceding days as a pseudo-observation of the subsurface temperature. Next, the road weather model is run with a few days offset. It first uses the recent, historical weather data and then the available forecasts. This approach exploits the fact that the energy balance models tend to “forget” their initial conditions and converge to the baseline solution. The experimental verification was conducted using the Model of the Environment and Temperature of Roads and the data from a road weather station in Warsaw over a period of two years. The additional forecast error introduced by the proposed pseudo-observational initialization averages 1.2 °C in the first prediction hour and then decreases in time. The paper also discusses the use of Digital Surface Models to take into account the shading effects, which are an essential source of forecast errors in urban areas. Limiting the use of in-situ sensors opens a perspective for an economical, largescale implementation of road meteorological models.

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Development of Asphalt Pavement Temperature Model for Tropical Climate Conditions in West Bali Region

Procedia Engineering ◽

10.1016/j.proeng.2015.11.126 ◽

2015 ◽

Vol 125 ◽

pp. 474-480 ◽

Cited By ~ 3

Author(s):

I. Made Agus Ariawan ◽

Bambang Sugeng Subagio ◽

Bagus Hario Setiadji

Keyword(s):

Asphalt Pavement ◽

Tropical Climate ◽

Temperature Model ◽

Climate Conditions ◽

Pavement Temperature

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Emission Characteristics of VOCs during Asphalt Pavement Construction

Materials Science Forum ◽

10.4028/www.scientific.net/msf.1035.999 ◽

2021 ◽

Vol 1035 ◽

pp. 999-1005

Author(s):

Yin Huai Ma ◽

Li Guo ◽

Shao Peng Wu ◽

Na Li ◽

Jun Xie

Keyword(s):

Asphalt Pavement ◽

Asphalt Binder ◽

Critical Factor ◽

Rolling Process ◽

Field Investigation ◽

Construction Technology ◽

Pavement Temperature ◽

Pavement Construction ◽

Complex Organic ◽

Vocs Emission

As the important part of expressway, the construction technology of asphalt pavement will contribute to the production of greenhouse gases and other volatile organic compounds (VOCs), which has a significant impact on the environment. In order to further analyze the composition, distribution and release of VOCs during asphalt pavement construction, the VOCs emission during paving and rolling were measured through field investigation and sampling. The results show that there are approximately 100 kinds of VOCs substances detected due to the complex organic component of asphalt binder, which is a critical factor to influence the VOCs emission during asphalt pavement construction. During the paving process, the largest VOCs release is 1015.05 ug/m3. With the increase of rolling times, the pavement temperature gradually decrease, and the VOCs emission drops to 266.73 ug/m3. The content of the 10 kinds of substances with the highest concentration accounts for more than 50% of the total VOCs content, in which the proportion of aliphatic hydrocarbons (ALH) and oxygenated hydrocarbon (O-HYD) of the paving process are the highest, while the proportion of aromatic hydrocarbons (ARH) is dominated in the rolling process. The results are vulnerable to the external environment, especially at lower emission level. The relevant research results have certain guiding significance for the control and treatment of harmful gas emission in the construction process of asphalt pavement.

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