螺旋匝道（桥）小客车横向行驶特性实测研究

doi:10.3969/j.issn.0258-2724.20170824

徐进^1,,
李建兴²,
林伟³,
崔强¹,
吴国雄⁴,
杨奎²

基金项目:国家自然科学基金资助项目（51678099）；国家重点研发计划课题（2016YFB0100905）；交通运输部应用基础研究（主干学科）项目（2015319814050）.

详细信息

作者简介:
徐进（1977—），男，教授，工学博士，博士生导师，研究方向为山区公路路线设计理论与方法、人-车-路系统协同、交通安全以及驾驶行为，电话：13228102668，E-mail：yhnl_996699@163.com

中图分类号:U412.3; U491.2
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出版历程
- 收稿日期:2017-11-23
- 修回日期:2019-04-11
- 网络出版日期:2019-07-05
- 刊出日期:2019-12-01

Field Tests on Lateral Operational Characteristics of Passenger Cars on Helical Ramps (Bridges)

摘要

摘要:螺旋匝道和螺旋桥的数量近年来与日俱增，但其驾驶行为模式和汽车运行特征一直未得到明确，为此，在涪陵长江一桥、乌江二桥、重庆融侨大道和涪陵金凯装饰城环形高架4处地点开展了螺旋匝道实车驾驶实验，采集了自然驾驶状态下的汽车连续行驶轨迹、横向加速度以及周围行驶环境等信息. 基于自然驾驶数据，得到了螺旋匝道范围内汽车横向加速度的变化模式、幅值特性、影响因素，以及驾驶人的车道使用特性. 研究结果表明：汽车横向加速度幅值在螺旋匝道范围内的变化趋势有多种模式，包括保持恒定、单调上升、单调下降、鼓型等；内圈匝道的横向加速度高于外圈；在单向行驶匝道上，横向加速度实测值远高于规范中的推荐值甚至超出可忍受范围，导致一部分被试行驶时横向舒适性较差；匝道半径和行驶空间对横向加速度幅值有显著影响，行驶空间保持一定时，横向加速度与匝道半径成负相关关系；单幅混合双向行驶的螺旋匝道，横向加速度幅值最低；对于单向双车道螺旋匝道，不管是上行方向还是下行方向，使用内侧车道是占主要比例的驾驶行为.
- 互通立交/
- 螺旋匝道/
- 螺旋展线/
- 横向加速度/
- 车道使用/
- 行驶特性/
- 交通安全
Abstract:Helical ramps and helical bridges are widely used in recent years, however the driving patterns and dynamic characteristics of vehicles running on them are still unclear. Therefore, to obtain the driving pattern of passenger cars on helical ramps (bridge), driving tests using real cars were carried out on Fuling Yangtze River Bridge, Second Fuling Wujiang River Bridge, Rongqiao Helical Bridge and Jinkai Helical Bridge in Chongqing. Trajectory and lateral acceleration speed of cars under drivers’ naturalistic driving were continuously collected, as well as environment information. Based on naturalistic driving data, the variation, amplitude and influencing factors of speed and lateral acceleration were obtained, together with lane usage pattern. It was found that diversified lateral acceleration patterns on helical ramps were observed, such as stabilized, increasing, deceasing, and drum-typed. Larger lateral acceleration were recorded on ramps along the inner ring than on ramps along the outer ring. Lateral acceleration measured on some one-way ramps are significantly higher than the recommended valve in highway design guidelines and even exceeding the unbearable threshold, which cause passengers discomfort in side direction. Ramp radius and driving space greatly affect lateral acceleration, lateral acceleration drops as ramp radius increases if driving space holds constant, and the smallest lateral acceleration was measured on mixed two-way helical ramp. For one-way helical ramps with two lanes, regardless of on upward ramp or downward ramp, driving on inside lane accounted for a major proportion of driving patterns.
- interchange/
- helical ramp/
- helical curves/
- lateral acceleration/
- lane occupation/
- driving behavior/
- road safety

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图 1试验对象

Figure 1.Test roads in this study

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图 2涪陵长江一桥螺旋匝道横向加速度

Figure 2.Lateral acceleration on helical ramps of Fuling Yangtze River Bridge

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图 3涪陵乌江二桥螺旋匝道横向加速度

Figure 3.Lateral acceleration on helical ramps of Second Fuling Wujiang River Bridge

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图 4重庆融侨大道螺旋桥横向加速度

Figure 4.Lateral acceleration on Rongqiao Helical Bridge

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图 5螺旋匝道上的超车

Figure 5.Overtaking on helical ramps

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图 6涪陵金凯装饰城环形高架横向加速度

Figure 6.Lateral accelerate on Jinkai Helical Bridge

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图 7螺旋匝道上避让对向来车

Figure 7.Avoiding on helical ramps

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图 8螺旋匝道上的横向加速度模式

Figure 8.Patterns of lateral acceleration on helical ramps

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图 9横向加速度均值点计算示意

Figure 9.Calculation of average ofaon helical ramps

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图 10横向加速度统计特征

Figure 10.Statistic characteristics of lateral acceleration

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图 11螺旋匝道横向加速度-半径箱形图

Figure 11.Relationship between lateral acceleration versus curve radius on helical ramps

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图 12螺旋匝道横向加速度-超高率箱形图

Figure 12.Relationship between lateral acceleration versus super-elevation rates on helical ramps

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图 13WJSB上行匝道入口汽车行驶轨迹类型.

Figure 13.Vehicle tracks on entrance of upward ramps of Second Fuling Wujiang River Bridge

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表 1试验对象的主要技术参数

Table 1.Main technical parameters of test roads

试验对象	设计速度/ （km•h⁻¹）	横断面形式	每幅车道数/道	结构形式	纵坡坡度/%	平曲线半径/m	超高率/%	匝道层数/层	限速值/ （km•h⁻¹）	被试编号
YZB	20	双幅分向行驶	1	独柱墩形式	4.5	上行匝道 39.53，下行匝道 50.00	6	2	20	D6～D15
WJSB	30	双幅分向行驶	2	单墩悬挑横梁式连续梁	4.5	上行匝道 51.00，下行匝道 38.25	4	2	30	D6～D13
RQB	40	双幅分向行驶	2	门型墩多跨连续梁	6.0	中间带半径 55.00	2	2	40	D1～D4；D10～D15
JKRB	20	单幅双向混合行驶	2	门型墩多跨连续梁	5.0～6.0	30.00	0	2	20	D8～D16

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表 2螺旋匝道横向加速度统计值以及特征分位值

Table 2.Statistics and characteristic percentiles of lateral acceleration on helical ramps m/s ²

参数类别	最大值	均值	百分位值/%
参数类别	最大值	均值	15	25	50	75	85	90	95
a均值	3.92	2.21	1.47	1.68	2.28	2.73	2.89	3.01	3.18
a峰值	4.40	2.70	1.91	2.15	2.77	3.21	3.43	3.55	3.69

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表 3位于不同舒适度区间的 $a $ 数据点比例

Table 3.Data ratio of lateral acceleration in different comfortable range %

数据类别	舒适	比较舒适	不舒适	不可忍受
a均值	24.0	58.3	17.7	0
a峰值	6.5	48.0	44.5	1.0

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表 4WJSB螺旋匝道车道使用情况统计

Table 4.Lane occupation on Second Fuling Wujiang River Bridge 次

匝道坡向	驾驶人														合计
	D6		D7		D8		D9		D10		D11		D12		合计
	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧
上行匝道	4	0	4	0	0	6	1.5	3.5	1	4	3	0	3	0	16.5	13.5
下行匝道	4	0	4	0	6	0	5	0	0	5	0	3	1	2	20	10

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表 5RQB桥车道使用情况统计

Table 5.Lane occupation on Rongqiao Helical Bridge 次

匝道坡向	驾驶人												合计
	D1		D2		D3		D4		D10		D11		合计
	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧	内侧	外侧
上行方向	3.5	0.5	4	0	4	0	1	2	5	0	4.5	0.5	22	3
下行方向	4	0	4	0	4	0	3	0	4	1	3	2	22	3

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