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青藏高原高等级道路路基路面温度变化特征

权磊 田波 牛开民 谢晋德 何哲 张颖辉

权磊, 田波, 牛开民, 谢晋德, 何哲, 张颖辉. 青藏高原高等级道路路基路面温度变化特征[J]. 交通运输工程学报, 2017, 17(2): 21-30.
引用本文: 权磊, 田波, 牛开民, 谢晋德, 何哲, 张颖辉. 青藏高原高等级道路路基路面温度变化特征[J]. 交通运输工程学报, 2017, 17(2): 21-30.
QUAN Lei, TIAN Bo, NIU Kai-min, XIE Jin-de, HE Zhe, ZHANG Ying-hui. Temperature variation properties of pavements and subgrades for high-grade roads on Qinghai-Tibet Plateau[J]. Journal of Traffic and Transportation Engineering, 2017, 17(2): 21-30.
Citation: QUAN Lei, TIAN Bo, NIU Kai-min, XIE Jin-de, HE Zhe, ZHANG Ying-hui. Temperature variation properties of pavements and subgrades for high-grade roads on Qinghai-Tibet Plateau[J]. Journal of Traffic and Transportation Engineering, 2017, 17(2): 21-30.

青藏高原高等级道路路基路面温度变化特征

基金项目: 

国家科技支撑计划项目 2014BAG05B00

交通运输部建设科技项目 2013 318 490 010

交通运输部建设科技项目 2014 318 J15 070

详细信息
    作者简介:

    权磊(1987-), 男, 陕西富平人, 交通运输部公路科学研究院助理研究员, 工学博士, 从事路基路面温度场研究

    田波(1973-), 男, 陕西商州人, 交通运输部公路科学研究院研究员, 工学博士

  • 中图分类号: U412.2

Temperature variation properties of pavements and subgrades for high-grade roads on Qinghai-Tibet Plateau

More Information
    Author Bio:

    QUAN Lei(1987-), male, assistant researcher, PhD, +86-10-62079598, quanleirioh@126.com

    TIAN Bo(1973-), male, researcher, PhD, +86-10-62079598, b.tian@rioh.cn

  • 摘要: 连续观测了青藏高原多年冻土区道路结构不同层位和天然大地不同深度处温度, 分析了不同层位日均温度的时空变化趋势、实时温度的频率分布特性与不同结构层材料的冻融特性。分析结果表明: 空气、面层、基层、路基和天然大地温度年度变化趋势均呈现明显的热季与冷季之分, 转换时间分别是4月份和9月份; 观测周期年内, 沥青混凝土路面路表日平均温度为-17 ℃~40 ℃, 水泥混凝土路面路表温度为-18 ℃~17 ℃, 沥青混凝土路面下的路基顶面以下0.8 m处温度波动范围为-2.8 ℃~6.3 ℃, 水泥混凝土路面下的路基顶面下0.7 m处温度波动范围为-3.4 ℃~5.4 ℃; 空气、沥青混凝土面层、水泥混凝土面层的温度和温度梯度频率分布均呈现出明显的单峰形态, 且峰值对应的温度或温度梯度与相应的年均值存在偏差; 基层、垫层和路基的温度频率分布均呈现多峰并存的形态, 分别与冷季、热季、冷热季转换期相对应; 分析周期年内沥青混凝土路面和水泥混凝土路面的路表冻融次数分别为182、178; 沥青混凝土与水泥混凝土冻结融化持续时间频率分布均呈现主峰+多副峰的形态, 主峰对应的持续时间分别为0~2 h和18~20 h。可见, 在多年冻土区, 可优先选择水泥混凝土路面, 以利于冻土的保护, 沥青混凝土与水泥混凝土配合比设计均应验证抗冻融耐久性能。

     

  • 图  1  天然大地温度传感器布设

    Figure  1.  Temperature sensor layout of natural earth

    图  2  沥青混凝土道路温度传感器布设

    Figure  2.  Temperature sensor layout of asphalt concrete road

    图  3  水泥混凝土道路温度传感器布设

    Figure  3.  Temperature sensor layout of cement concrete road

    图  4  空气日平均温度

    Figure  4.  Daily mean temperatures of air

    图  5  沥青混凝土路面路表日平均温度

    Figure  5.  Daily mean temperatures of asphalt concrete pavement surface

    图  6  水泥混凝土路面路表日平均温度

    Figure  6.  Daily mean temperatures of cement concrete pavement surface

    图  7  路基顶面和天然地表日平均温度

    Figure  7.  Daily mean temperatures on subgrade surface and natural ground surface

    图  8  沥青混凝土道路温度分布曲线

    Figure  8.  Temperature distribution curves of asphalt concrete road

    图  9  水泥混凝土道路温度分布曲线

    Figure  9.  Temperature distribution curves of cement concrete road

    图  10  天然大地温度分布曲线

    Figure  10.  Temperature distribution curves of natural ground

    图  11  年平均温度对比

    Figure  11.  Comparison of annual mean temperatures

    图  12  空气与沥青混凝土路面温度频率分布

    Figure  12.  Temperature frequency distributions of air and asphalt concrete pavement

    图  13  空气与水泥混凝土路面温度频率分布

    Figure  13.  Temperature frequency distributions of air and cement concrete pavement

    图  14  水泥混凝土路面温度梯度频率分布

    Figure  14.  Temperature gradient frequency distributions of cement concrete pavement

    图  15  沥青混凝土路面基层与垫层温度频率分布

    Figure  15.  Temperature frequency distributions of base layer and sub-base for asphalt concrete pavement

    图  16  水泥混凝土路面基层与垫层温度频率分布

    Figure  16.  Temperature frequency distributions of base layer and sub-base for cement concrete pavement

    图  17  沥青混凝土路面的路基温度频率分布

    Figure  17.  Temperature frequency distributions of subgrade for asphalt concrete pavement

    图  18  水泥混凝土路面的路基温度频率分布

    Figure  18.  Temperature frequency distributions of subgrade for cement concrete pavement

    图  19  空气与沥青混凝土路面在冻融循环过程中正温持续时间频率分布

    Figure  19.  Frequency distributions of positive temperature lasting times of air and asphalt concrete pavement during freeze-thaw cycle

    图  20  空气与沥青混凝土路面在冻融循环过程中负温持续时间分布频率

    Figure  20.  Frequency distributions of negative temperature lasting times of air and asphalt concrete pavement during freeze-thaw cycle

    图  21  空气与水泥混凝土面层在冻融循环过程中正温持续时间分布频率

    Figure  21.  Frequency distributions of positive temperature lasting times of air and cement concrete surface during freeze-thaw cycle

    图  22  空气与水泥混凝土面层在融循环过程中负温持续时间分布频率

    Figure  22.  Frequency distributions of negative temperature lasting times of air and cement concrete surface during freeze-thaw cycle

    表  1  道路不同层位的冻融指数

    Table  1.   Freeze-thaw indexes of different layers of roads

    下载: 导出CSV
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  • 收稿日期:  2016-11-21
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