Characteristics and application of road absorbing solar energy 被引量：1

Characteristics and application of road absorbing solar energy

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摘要 If the heat of road surface can be stored in summer, the road surface temperature will be decreased to prevent permanent deformation of pavement. Besides, if the heat stored is released, it can supply heat for buildings or raise the road surface temperature for snow melting in winter. A road-solar energy system was built in this study, and the heat transfer mechanism and effect of the system were analyzed according to the monitored solar radiant heat, the solar energy absorbed by road and the heat stored by soil. The results showed that the road surface temperature was mainly affected by solar radiation, but the effect is hysteretic in nature. The temperature of the solar road surface was 3~C-6~C lower than that of the ordinary road surface. The temperature of the solar road along the vertical direction was 2~C-5~C lower than that of the ordinary road. The temperature difference increased as the distance to the heat transfer tubes decreased. The average solar collector efficiency of the system was 14.4%, and the average solar absorptivity of road surface was 36%. If the heat of road surface can be stored in summer, the road surface temperature will be decreased to prevent permanent deformation of pavement. Besides, if the heat stored is released, it can supply heat for buildings or raise the road surface temperature for snow melting in winter. A road-solar energy system was built in this study, and the heat transfer mechanism and effect of the system were analyzed according to the monitored solar radiant heat, the solar energy absorbed by road and the heat stored by soil. The results showed that the road surface temperature was mainly affected by solar radiation, but the effect is hysteretic in nature. The temperature of the solar road surface was 3~C-6~C lower than that of the ordinary road surface. The temperature of the solar road along the vertical direction was 2~C-5~C lower than that of the ordinary road. The temperature difference increased as the distance to the heat transfer tubes decreased. The average solar collector efficiency of the system was 14.4%, and the average solar absorptivity of road surface was 36%.

作者 Zhihua ZHOU Shan HU Xiaoyan ZHANG Jian ZUO

机构地区 School of Environmental Science and Technology School of Natural and Built Environments

出处《Frontiers in Energy》 SCIE CSCD 2013年第4期525-534,共10页 能源前沿（英文版）

关键词 solar energy road-solar energy system road surface temperature solar absorptivity of road surface solar collector efficiency of system solar energy, road-solar energy system, road surface temperature, solar absorptivity of road surface, solar collector efficiency of system

分类号 TK51 [动力工程及工程热物理—热能工程] TK515 [动力工程及工程热物理—热能工程]

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