沥青混合料内部空隙分布特征(英文)

WANG Hai-nian; HAO Pei-wen; LU: Guang-yin

doi:10.19818/j.cnki.1671-1637.2009.01.002

沥青混合料内部空隙分布特征(英文)

doi: 10.19818/j.cnki.1671-1637.2009.01.002

1.
长安大学特殊地区公路工程教育部重点实验室, 陕西西安 710064
2.
民航深圳安全监督管理办公室, 广东深圳 518128

基金项目:

National Natural Science Fund Project of China 50808023

Young Teacher Fund Project of Changʾan University 2008Q10

详细信息

中图分类号: U414.18
计量
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- 被引次数: 0
出版历程
- 收稿日期: 2008-11-10
- 刊出日期: 2009-02-25

Distribution properties of internal air voids in asphalt mixtures

1.
Key Laboratory for Special Area Highway Engineering of Ministry of Education, Chang'an University, Xi'an 710064, Shaanxi, China
2.
CAAC Shenzhen Safety Oversight and Management Office, Shenzhen 518128, Guangdong, China

Funds:

National Natural Science Fund Project of China 50808023

Young Teacher Fund Project of Changʾan University 2008Q10

More Information

Author Bio:
WANG Ha-i nian(1977-), Male, Lianshui, Jiangsu, Lecturer of Changʾan University, PhD, Research on PavementMaterials, +86-29-82334824, wanghn@chd.edu.cn

摘要

摘要: 利用X-rayCT无损检测设备分别对Marshall与SGC成型的AC-16、SMA-16与OGFC-16三种沥青混合料的内部结构进行扫描, 利用数字图像处理技术, 分析了混合料内部的空隙分布特征。分析结果表明: 沥青混合料内部空隙呈不均匀分布状态, 其变异性受成型方式与级配型式的影响。在试件的高度方向, SGC成型试件的内部空隙总体上呈现“两头大、中间小”的特性, 但Marshall成型试件的空隙分布特征并不显著。在试件的横向, AC-16与SMA-16试件的空隙较多地分布在试件边缘, 试件呈“外疏内密”状态。
- 路面工程 /
- 沥青混合料 /
- 内部空隙 /
- 空间分布 /
- 计算机层析技术
Abstract: X-ray computed tomography(CT) technology was adopted to scan the internal structures of AC-16, SMA-16 and OGFC-16 mixture specimens compacted using Marshall and Superpave gyratory compactor(SGC) methods. Digital image processing technology was adopted to analyze the spatial distribution of their internal air voids. The result shows that the distributions of air voids are not uniform in mixture specimens, and they vary greatly with the compacting styles and gradations of asphalt mixtures. Throughout the specimen height, air void percents are bigger on the top and at the bottom, and are smaller in the middles of the specimens compacted by SGC method, whereas the distribution variances are not marked for the specimens compacted by Marshall method. Throughout the cross sections of the specimens, air voids distribute more in the outside parts than in the middle parts for AC-16 and SMA-16 mixtures. 3 tAbs, 11 figs, 10 refs.
- pavement engineering /
- asphalt mixture /
- internal air void /
- spatial distribution /
- CT

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图 1 CT扫描层位置

Figure 1. CT scanning slice positions

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图 2 Marshall成型AC-16试件的CT图片

Figure 2. CT images of AC-16 specimen compacted by Marshall

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图 3 SGC成型AC-16试件的CT图片

Figure 3. CT images of AC-16 specimen compacted by SGC

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图 4 Marshall成型SMA-16试件的CT图片

Figure 4. CT images of SMA-16 specimen compacted by Marshall

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图 5 SGC成型SMA-16试件的CT图片

Figure 5. CT images of SMA-16 specimen compacted by SGC

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图 6 Marshall成型OGFC-16试件的CT图片

Figure 6. CT images of OGFC-16 specimen compacted by Marshall

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图 7 SGC成型OGFC-16试件的CT图片

Figure 7. CT images of OGFC-16 specimen compacted by SGC

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图 8 SGC试件内部空隙分布

Figure 8. Air void distributions of mixture specimens compacted by SGC

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图 9 Marshall试件内部空隙分布

Figure 9. Air void distributions of mixture specimens compacted by Marshall

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图 10 0空隙分布区域Fig. 10 Different regions of void distribution

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图 11 沥青混合料空隙分布

Figure 11. Void distributions of mixture specimens

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表 1 Passing percents of three gradations

Table 1. Passing percents of three gradations

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表 2 Performance parameters of asphalt mixtures

Table 2. Performance parameters of asphalt mixtures

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表 3 Technical data of CT system

Table 3. Technical data of CT system

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参考文献(10)

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