EXPERIMENTAL STUDY ON COMPRESSIVE STRENGTH OF POLYPROPYLENE FIBER REINFORCED CEMENT STABILIZED MACADAM

Zhang Peng; Li Qingfu; Huang Chengkui

doi:10.13204/j.gyjz200803025

Volume 38 Issue 3

Dec. 2014

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Article Navigation > INDUSTRIAL CONSTRUCTION > 2008 > 38(3): 94-96

Wang Yan, Zheng Jie. STUDY ON THE PRYING FORCE OF HIGH STRENGTH BOLT IN EXTENDED END-PLATE CONNECTION[J]. INDUSTRIAL CONSTRUCTION, 2008, 38(9): 99-103. doi: 10.13204/j.gyjz200809028

Citation:

Zhang Peng, Li Qingfu, Huang Chengkui. EXPERIMENTAL STUDY ON COMPRESSIVE STRENGTH OF POLYPROPYLENE FIBER REINFORCED CEMENT STABILIZED MACADAM[J]. INDUSTRIAL CONSTRUCTION, 2008, 38(3): 94-96. doi: 10.13204/j.gyjz200803025

Wang Yan, Zheng Jie. STUDY ON THE PRYING FORCE OF HIGH STRENGTH BOLT IN EXTENDED END-PLATE CONNECTION[J]. INDUSTRIAL CONSTRUCTION, 2008, 38(9): 99-103. doi: 10.13204/j.gyjz200809028

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EXPERIMENTAL STUDY ON COMPRESSIVE STRENGTH OF POLYPROPYLENE FIBER REINFORCED CEMENT STABILIZED MACADAM

doi: 10.13204/j.gyjz200803025

1.
1. College of Water Conservancy &Environmental Engineering,Zhengzhou University,Zhengzhou 450002;
2.
2. College of Civil and Water Conservancy,Dalian University of Technology,Dalian 116024

Received Date: 2007-04-04
Publish Date: 2008-03-20

Abstract

Abstract

Based on plenty of experimental studies, the effect of curing period of specimens, volume content of polypropylene fiber and cement content on compressive strength of cement stabilized macadam is analyzed. The study results indicate that the addition of polypropylene fiber has certain reinforcement to the compressive strength of cement stabilized macadam. The compressive strength is increasing with the increase of curing period. Within the range of the fiber content that is less than 1j in this study, there is a tendency of increase in compressive strength and tensile strength with the increase of polypropylene fiber volume content. With the increase of cement content, the compressive strength of cement stabilized macadam is increasing in linearity.
- polypropylene fiber,
- cement stabilized macadam,
- compressive strength,
- curing period,
- cement content

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References(10)

References

[2] 黄学文, 张正锋. HNF-6 高效缓凝阻裂剂在水泥稳定碎石基层中的应用研究. 公路交通科技, 2001, 18 (2) : 13-15

蒋应军,陈忠达,彭波,等.密实骨架结构水泥稳定碎石路面配合比设计方法及抗裂性能. 长安大学学报(自然科学版),2002, 22 (4) : 9-12

[3] 杨红辉, 王建勋, 郝培文, 等. 纤维在水泥稳定碎石基层中的应用. 长安大学学报(自然科学版), 2006, 26 (3) : 14-17

[4] JTJ 014-1997 公路沥青路面设计规范

[5] JTJ 057-94 公路工程无机结合料稳定材料试验规程

[6] 朱江. 聚丙烯纤维在高性能混凝土中的应用研究. 工业建筑,2001, 31 (1) : 35-38

[7] 孙道胜, 邓敏, 唐明述, 等. 聚丙烯纤维增强膨胀混凝土阻裂抗渗性能研究. 工业建筑, 2004, 34 (3) : 31-34

[8] 王平, 肖建庄, 陈瑞生, 等. 聚丙烯纤维对高性能混凝土高温后力学性能的影响试验研究. 工业建筑, 2005, 35 (11) : 49-52

[9] 潘兆平, 黄晓明. 水泥稳定碎石路面基层材料水泥剂量范围试验. 南京建筑工程学院学报, 1998 (4) : 21-26

[10] 丛林, 郭忠印, 暨育雄, 等. 半刚性基层材料性能参数的试验研究. 建筑材料学报, 2001, 4 (4) : 385-390

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