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考虑多模式失效概率的长下坡路段重型卡车事故预测模型

尹燕娜 温惠英

尹燕娜, 温惠英. 考虑多模式失效概率的长下坡路段重型卡车事故预测模型[J]. 交通信息与安全, 2022, 40(3): 1-9. doi: 10.3963/j.jssn.1674-4861.2022.03.001
引用本文: 尹燕娜, 温惠英. 考虑多模式失效概率的长下坡路段重型卡车事故预测模型[J]. 交通信息与安全, 2022, 40(3): 1-9. doi: 10.3963/j.jssn.1674-4861.2022.03.001
YIN Yanna, WEN Huiying. Development of Crash Prediction Models Involving Heavy-duty Trucks over Long Downhill Segments Considering Multi-mode Failure Probability[J]. Journal of Transport Information and Safety, 2022, 40(3): 1-9. doi: 10.3963/j.jssn.1674-4861.2022.03.001
Citation: YIN Yanna, WEN Huiying. Development of Crash Prediction Models Involving Heavy-duty Trucks over Long Downhill Segments Considering Multi-mode Failure Probability[J]. Journal of Transport Information and Safety, 2022, 40(3): 1-9. doi: 10.3963/j.jssn.1674-4861.2022.03.001

考虑多模式失效概率的长下坡路段重型卡车事故预测模型

doi: 10.3963/j.jssn.1674-4861.2022.03.001
基金项目: 

国家自然科学基金项目 52172345

详细信息
    作者简介:

    尹燕娜(1987—),博士研究生. 研究方向:道路交通安全. E-mail:1241085280@qq.com

    通讯作者:

    温惠英(1965—),博士,教授. 研究方向:道路交通安全、交通规划等. E-mail:hywen@scut.edu.cn

  • 中图分类号: U491.31

Development of Crash Prediction Models Involving Heavy-duty Trucks over Long Downhill Segments Considering Multi-mode Failure Probability

  • 摘要: 为挖掘多模式失效概率与长下坡路段重型卡车事故之间的关系,建立了重型卡车在长下坡路段的多模式失效概率与车辆事故之间的关系模型。并针对重型卡车在长下坡路段可能的失效模式,如侧滑、侧翻、视距不足、制动失效,在此基础上建立了多模式失效概率预测模型;通过蒙特卡罗法模拟并求解单模式失效的概率,宽界限法求解失效系统的多模式失效概率;将多模式失效概率作为解释变量与其他道路因素结合,分别建立泊松模型、随机效应泊松模型、随机参数泊松模型,将多模式失效概率与重型卡车事故建立函数关系;对比3种模型的拟合优度指标,优选出最优事故预测模型,用来挖掘重型卡车事故与多模式失效概率之间的关系。以华盛顿州71段长下坡10年的重型卡车事故数据及道路设计数据进行方法验证。结果表明:随机参数泊松模型与随机效应泊松模型的拟合优度相差较小,二者均优于泊松模型;当考虑多模式失效概率时,平曲线半径、纵坡坡度、超高对重型卡车事故的影响均不显著,即三者的影响被削弱,尤其是平曲线半径和超高,多模式失效概率的弹性(0.239)远大于二者的弹性(平曲线半径和超高的弹性分别仅为0.097和0.002);重型卡车的事故与多模式失效概率近似线性关系,且截距不为0。即多模式失效概率可用于道路安全分析的表征指标,但与事故概率不等价。

     

  • 图  1  车辆在弯坡路段的受力分析

    Figure  1.  Force analysis of vehicles on combination sections of vertical and horizontal curve

    图  2  预测事故数与实际事故数比较

    Figure  2.  Comparison between predicted and actual crashes value

    图  3  重型卡车事故数与多模式失效概率的关系

    Figure  3.  Relationship between heavy truck crash values and multi-mode failure probability

    表  1  固定变量及取值

    Table  1.   Fixed variables and values

    符号 变量解释 变量值
    m 车辆的总重量/kg 20 000
    m0 满载质量/kg 30 000
    T0 制动器的初始温度/℃ 本文取130
    g 重力加速度/(m/s2) 9.81
    ρθ 空气密度/(kg/m3) 1.225 8
    A2 重型车辆的迎风面积/m2 6
    κ 车辆的空气阻力系数 1
    z0 主传动比 5.833
    zv 各档传动比
    q 后轮制动器数 4
    η 传动效率 0.83
    m1 所有后轮承受质量之和/kg 总质量的90%
    γ 制动力分配系数/% 27.2
    R1 后轮动力半径/m 0.515
    R2 后轮滚动半径/m 0.527
    m2 制动鼓质量/kg 62.268
    A1 制动鼓的表面积/m2 0.347
    c 制动鼓的比热容/(J/kg·℃) 482
    系数 τ0 = m/m0τ1 = 66.34;τ = 1.0475; τ2 = 0.050 1
    L 路段长度/km
    hr/hg 0.25
    rφ 侧倾率 0.05
    B/2hg 0.58
    μ2 湿滑路面提供的附着系数 0.4
    下载: 导出CSV

    表  2  变量的统计特征

    Table  2.   Statistical characteristics of variables

    变量 均值 标准差 最大值 最小值
    重型卡车事故数 9.085 14.602 80 0
    暴露变量
    路段长度/km 3.676 3.950 19.614 1.030
    年平均日交通量/(辆/天) 146 33 250 64 165 789 531
    交通情况变量
    法定限速/(km/h) 84.416 15.623 112.63 40.225
    卡车的百分比/% 12.788 8.959 38.949 0.184
    道路设计参数
    平曲线半径/m 0.416 0.438 2.329 0.011
    纵坡/% 3.996 0.815 6.478 2.804
    超高/% 1.646 3.231 10 0
    多模式失效概率 0.391 0.311 1 0
    下载: 导出CSV

    表  3  考虑多模式失效概率的随机效应泊松模型估计结果

    Table  3.   estimation results of crash prediction model considering multi-mode failure probability

    变里名称 泊松模型 随机效应泊松模型 随机参数泊松模型
    系数值 标准误 P 系数值 标准误 P 系数值 标准误 P 弹性
    截距项 -9.595*** 0.711 0 -8.769*** 0.711 -8.315*** 0.719 0
    参数分布标准差 0.585*** 0.049 0.250*** 0.042
    暴露变量
    路段长度的对数 0.124*** 0.011 0 0.142*** 0.012 0 0.138*** 0.012 0 0.506
    年平均日交通量对数 0.967*** 0.055 0 0.941*** 0.058 0 0.903*** 0.059 0 7.805
    参数分布标准差 0.057*** 0.005
    交通情况变量
    法定限速 0.015*** 0.004 0 0.006* 0.004 0.094 0.005 0.004 0.250 0.383
    卡车的百分比 0.018** 0.009 0.037 0.029*** 0.009 0.001 0.032*** 0.009 0.001 0.412
    道路设计参数
    平曲线半径 -0.11 0.144 0.442 0.167 0.15 0.265 0.234 0.151 0.123 0.097
    纵坡 0.182** 0.074 0.014 0.077 0.086 0.369 0.067 0.087 0.441 0.267
    超高 -0.046*** 0.015 0.002 -0.007 0.016 0.642 0.001 0.016 0.934 0.002
    多模式失效概率 0.459** 0.2 0.022 0.541** 0.212 0.011 0.610*** 0.215 0.005 0.239
    样本数量 71 71 71
    参数数量 9 10 11
    对数似然值 -232.031 -183.496 -182.502
    仅含常数项的对数似然值 -643.079 -1653.35 -1653.35
    麦克费登, 0.639 0.889 0.89
    A/C 482.1 387 387
    MAD 4.077 1.02 1.012
    均方根误差 6.613 1.346 1.316
    注:***,**,* 分别表示在1%、5%和10%水平上显著。
    下载: 导出CSV
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  • 收稿日期:  2022-01-01
  • 网络出版日期:  2022-07-25

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