Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (2): 297-311.doi: 10.13229/j.cnki.jdxbgxb20220175

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Dry shrinkage in cement⁃stabilized macadam: a review

Yang ZHANG(),Ao-peng WANG,Jing-lin ZHANG,Tao MA(),Si-yu CHEN   

  1. School of Transportation,Southeast University,Nanjing 211189,China
  • Received:2022-02-27 Online:2023-02-01 Published:2023-02-28
  • Contact: Tao MA E-mail:yang-zhang@seu.edu.cn;matao@seu.edu.cn

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Abstract:

The objective of this study is to analyze the drying shrinkage behavior of cement-stabilized macadam(CSM) and improve its anti-cracking performance. In this paper, previous studies conducted on the mechanism of shrinkage and cracking in CSM and shrinkage mitigation strategies are reviewed, and summarized. The drying shrinkage performance of CSM materials is mainly studied through shrinkage mechanism and shrinkage prevention and improvement measures. As a cement-based material, the existing research on the drying shrinkage mechanism of CSM mainly refers to the available dry shrinkage mechanism of cement concrete. Four models are always used to characterize the shrinkage at different stages according to the change of relative humidity(RH) inside the mixture: capillary tension, surface free energy, disjoining pressure and interlayer water movement. The drying shrinkage mitigation strategies of CSM have achieved a series of results in recent years. According to the different mechanisms CSM shrinkage performance improvement methods can be classified into gradation, cement content, CSM molding method, and additive modification. The results show that reducing the amount of cement, adopting the skeleton of dense gradation, employing vibration stirring or vibration compaction, and adding rubber, steel slag, fiber or other modifiers can effectively reduce the drying shrinkage of CSM and improve its shrinkage performance and road serviceability. Additionally, the shrinkage mechanism, comprehensive optimization method, drying shrinkage measurement and evaluation method and shrinkage prediction model of CSM are assessed. The development trend and prospect of the shrinkage performance of CSM are generated.

Key words: highway and railway engineering, drying shrinkage, review, cement-stabilized macadam, shrinkage mitigation strategies

CLC Number: 

  • U414

Fig.1

Schematic representation of the moist concrete as a multiphase porous material"

Fig.2

Schematic diagram of test device by Splittgerber"

Fig.3

Characterization of the distance between adjacent particles under different RH"

Fig.4

Evolution process of interlayer water movement"

Fig.5

Dry shrinkage process"

Fig.6

Relationship between shrinkage coefficient and time"

Fig.7

Interface diagrams of specimens under different types of forming methods"

Fig.8

Influence of fiber on the water loss of CSM"

Table 1

Comparison of adding fiber regulation methods"

纤维类型纤维长度/mm掺量干缩条件水泥含量/%龄期/d效果/%文献
聚酯纤维500%~1.5%T=20 ℃,RH=60%425~405.9~27.244
聚乙烯醇纤维120.9 kg/m3T=20 ℃,RH=60%3.61009.646
1817.2
2424.0
3019.35
120.6~1.2 kg/m3T=20 ℃,RH=60%3.2~4908.3847
1815.79
2422.49
3017.96
聚丙烯纤维-0.5%T=20 ℃,RH=60%5.39016.749
10~200.1%T=40 ℃5-4251
191.0%T=20 ℃,RH=60%5720.253
玻璃纤维60.15%T=20 ℃,RH=50%4717.355
1231.5
1846.8
玄武岩纤维250.1%自然条件下4255156
120.05%T=20 ℃,RH=60%42813.359

Fig.9

Microscopic image of CSM with rubber"

Table 2

Comparison of other additives"

外掺剂种类外掺剂含量/%效果/%文献
纳米层状材料水泥的10%2066
建筑垃圾复合粉体材料2.04067
粉煤灰5~1041.168
沥青乳液2~321.471
废旧沥青混合料2516.572
X型凹凸棒石黏土水泥的5%13.773
Y型凹凸棒石黏土水泥的10%7.4
Y型煅烧凹凸棒石黏土水泥的15%20.5
脱硫石膏5.06074
废弃食用油-1575
城市垃圾焚烧飞灰代替25%水泥25.976

Table 3

Comparison of drying shrinkage mitigation strategies of CSM"

调控方法调控机理所用材料或途径
改善级配骨料对干燥收缩变形的约束作用

1.采用骨架密实型级配(逐级填充法、贝雷法等);

2.在保证强度满足要求的基础上,减少水泥用量;

3.选择轻质骨料。

控制成型、养生混合料充分拌合,减少离析

1.采用振动搅拌、振动击实等成型方式,使材料充分拌合、碾压;

2.控制养生条件,延长养生龄期,避免早期破坏。

添加外掺剂

增韧作用、增塑、保水作用;

降低CSM的凝胶材料早期的化学收缩

1.添加钢渣、纤维(玄武岩纤维、合成纤维、玻璃纤维、矿纤维等)、

橡胶等常用减缩改性剂;

2.用粉煤灰、纳米层状材料等替代部分水泥。

Fig.10

Schematic diagram of drying shrinkage device"

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