期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

基于沥青-集料粘结性能的碎石封层技术性能影响因素研究 被引量:8

Research on Influencing Factors of Chip Seal Technical Performance Based on Asphalt-aggregate Bond Characteristics
原文传递
导出
摘要 基于沥青-集料间粘结性能角度,以沥青碎石封层技术性能影响因素为研究对象,采用Vialet方法对沥青碎石封层进行锤击试验,研究沥青、集料、集料预拌、水、埋入深度和碾压延迟时间对碎石封层技术性能的影响。通过试验分析,得出如下结论:乳化沥青碎石封层性能优于SBS改性沥青和基质沥青碎石封层,采用石灰岩集料的沥青碎石封层性能优于采用花岗岩集料的沥青碎石封层,乳化沥青碎石封层不需要预拌集料,水对沥青-集料间粘结性能影响很大,会导致集料损失,碎石封层集料残留率随集料埋入深度增加而增加,随碾压延迟时间增加而减少。 Based on asphalt-aggregate bond characteristics,the study aimed at the influencing factors of chip seal tech- nical performance. The Vialet test method was designed to analyse the influence of several factors on chip seal technical performance,which included asphalt type, aggregate type, aggregate pretreation, moisture, embedment depth and the delayed rolling time. The results show that the performance of emulsified asphalt chip seal is better than SBS-modified as- phalt and hot asphalt chip seal. Limestone aggregates perform better than granite in asphalt-aggregate bond characteris- tics. Aggregates needn't be pretreated before emulsified asphalt chip seal construction. Moisture plays an important role in asphalt-aggregate bond and leads to aggregate loss. The aggregate embedment depth and the delayed roiling time are also the significant factors affecting chip retention. The chip retention rate increases with the aggregate embedment depth increase and the delayed rolling time decrease.
作者 刘丽 杨森 郝培文
机构地区 西安建筑科技大学土木工程学院 中国民航机场建设集团公司 长安大学公路学院
出处 《武汉理工大学学报》 CAS CSCD 北大核心 2013年第11期52-57,共6页 Journal of Wuhan University of Technology
基金 国家自然科学基金(51108375 51108374) 陕西省重点学科建设专项资金(E01004)
关键词 道路工程 沥青-集料 碎石封层 Vialet试验 集料损失 集料残留率 road engineering asphalt-aggregate bond chip seal Vialet test aggregate loss chip retentionrate
分类号 U416.21 [交通运输工程—道路与铁道工程]
  • 相关文献

参考文献9

  • 1孙祖望.沥青路面养护维修技术的发展与新材料、新工艺、新技术的应用(一)[J].建设机械技术与管理,2004,17(8):22-25. 被引量:42
  • 2Waters J C. Investigating the Contribution of Sealing Chip Application Rates to the Early Failure of Chip Seals[R]. Christchurch: New Zealand Transport Agency, 2011.
  • 3Kodippily S, Henning T, Ingham J M. Detecting Flushing of Thin Sprayed Seal Pavements Using Pavement Management Data[J]. Journal of Transportation Engineering, 2012,138(5): 665-673.
  • 4Gransberg D D,Zaman M. Analysis of Emulsion and Hot Asphalt Cement Chip Seal Performance[J]. Journal of Trans- portation Engineering, 2005,131(3): 229-238.
  • 5Rahman F, Islam M S, Musty H, et al. Aggregate Retention in Chip Seal[J]. Journal of the Transportation Research Board, 2012,2267 (1) : 56-64.
  • 6Subrata Kumar Das B S. Evaluation of Asphalt-aggregate Bond and Stripping Potential[D]. Lubbock: Texas Tech Uni- versity, 2004.
  • 7Lee J, Kim Y R. Optimizing Rolling Patterns for Chip Seals Using Laboratory Aggregate Loss Performance Tests on Field Fabricated Samples[J]. Journal of Performance of Constructed Facilities, 2010,24(3): 249-257.
  • 8Senadheera S, Tock R W, Hossain M S, et al. A Testing and Evaluation Protocol to Assess Seal Coat Binder-aggregate Compatibility[R]. Lubbock: Texas Department of Transportation, 2006.
  • 9The South African National Roads Agency. TRH3 2007 Design and Construction of Surfacing Seals[S]. Pretoria: The South African National Roads Agency Ltd, 2007.

共引文献41

同被引文献43

引证文献8

二级引证文献34

武汉理工大学学报
2013年 第11期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部