Influence of Humidity on the Elastic Modulus and Axis Compressive Strength of Concrete in a Water Environment
Abstract
:1. Introduction
- The elastic modulus of single strength grade concrete has been researched in previous studies, however, the sensitivity of elastic modulus affected by humidity conditions of concrete with different strength grades was different.
- In the physical experiment of concrete elastic modulus, the research range of humidity was mostly dry and saturated humidity conditions, and there was no intermediate transient excessive humidity condition.
- The humidity level was expressed in terms of water content in previous studies, but the water content was an absolute quantity. The proportion of pores in concrete filled with water could be expressed by the moisture content.
2. Experimental Materials, Equipment, and Design
2.1. Experimental Materials and Equipment
2.2. Experimental Design
3. Experimental Methods
4. Experimental Results and Analysis
4.1. Water Saturation of Concrete
4.2. Axial Compressive Strength of Concrete
4.3. Elasticity Modulus of Concrete
5. Discussion
- Physically free water A large number of pores and microcracks existed in the concrete, and the concrete elasticity modulus was weakened. When the concrete structure was in a nonpressurized water environment, the water entered the active pores of the concrete under the action of capillary adsorption force, and the active pores were filled by free water. Since the volume modulus of water was different from the matrix, the free water in the active pores of concrete impeded the deformation of the matrix, and the rigidity of the pores and microcracks were enhanced in the compressive elastic deformation stage under the external load. In addition, it can be seen from microhydrodynamics that the surface tension and viscous force of the water in the pores were both large, which contributed to the shear modulus of concrete in the elastic stage and ultimately the elasticity modulus of saturated concrete was enhanced. For completely dry concrete, pores and microcracks were filled with air and the elasticity modulus of air was very small, therefore the elasticity modulus of dry concrete was lower than the saturated concrete.
- Chemically combined water The main hydration product of cement paste was C-S-H, which accounted for 60–70% of the total volume of hydration product, and its deformation characteristics directly influenced the macroscopic deformation characteristics of concrete. According to Hou et al. [29], the molecular structure diagram of C-S-H in the dry and saturated state are shown in Figure 8. The influence of the number of water molecules on the deformation of C-S-H was analyzed based on the perspective of microscopic molecular structure.
6. Conclusions
- The water saturation of concrete increased with an extension in immersion time. The lower the strength grade of concrete, the faster its water absorption rate and the higher the water saturation reached under the same immersion time condition.
- The concrete axial compressive strength decreased with an increase in water saturation, and the effect of water saturation was significant. The axial compressive strengths of concrete with strength grades C15, C20, and C30, under approximate saturation, decreased by 27.2%, 21.1%, and 20.8%, respectively, as compared with the completely dry state. The concrete axial compressive strength with low-strength grade was more sensitive to the water saturation.
- The concrete elasticity modulus increased with an increase in water saturation. The elasticity moduli of concrete with strength grades C15, C20, and C30, under a saturated state, were 1.18, 1.19, and 1.24 times higher as compared with the completely dry state, respectively. The elasticity modulus of the concrete with high-strength grade was more sensitive to the water saturation, under the same water saturation condition.
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Strength Grade | Water/Cement Ratio | Mix Proportion/kg·m−3 | ||||
---|---|---|---|---|---|---|
Water | Cement | Medium Sand | Small Stone | Middle Stone | ||
C15 | 0.65 | 158 | 243 | 729 | 709 | 709 |
C20 | 0.55 | 150 | 273 | 615 | 685 | 685 |
C30 | 0.42 | 165 | 391 | 581 | 646 | 646 |
Strength Grade | Completely Dry Group | Soaking Time/h | ||||
---|---|---|---|---|---|---|
3 | 10 | 24 | 72 | 240 | ||
C15 | A0 | A1 | A2 | A3 | A4 | A5 |
C20 | B0 | B1 | B2 | B3 | B4 | B5 |
C30 | C0 | C1 | C2 | C3 | C4 | C5 |
C15 | C20 | C30 | |||
---|---|---|---|---|---|
Water Saturation/% | Axial Compressive Strength/MPa | Water Saturation/% | Axial Compressive Strength/MPa | Water Saturation/% | Axial Compressive Strength/MPa |
0.00 | 16.41 | 0.00 | 21.48 | 0.00 | 28.29 |
47.56 | 14.87 | 71.63 | 19.85 | 47.29 | 26.67 |
78.30 | 13.30 | 80.48 | 18.55 | 78.05 | 24.45 |
97.99 | 12.45 | 80.90 | 17.75 | 81.51 | 23.50 |
99.59 | 12.07 | 92.75 | 17.33 | 90.48 | 23.31 |
100 | 11.94 | 100 | 16.94 | 100 | 22.42 |
C15 | C20 | C30 | |||
---|---|---|---|---|---|
Water Saturation/% | Elastic Modulus/GPa | Water Saturation/% | Elastic Modulus/GPa | Water Saturation/% | Elastic Modulus/GPa |
0 | 19.58 | 0 | 22.50 | 0 | 24.31 |
47.56 | 20.83 | 71.63 | 24.58 | 47.29 | 27.12 |
78.30 | 22.94 | 80.48 | 25.19 | 78.05 | 27.23 |
97.99 | 23.24 | 80.90 | 24.75 | 81.51 | 28.03 |
99.59 | 23.04 | 92.75 | 26.08 | 90.48 | 29.26 |
100 | 23.24 | 100 | 26.63 | 100 | 30.36 |
Strength Grade | Model Parameter | ||
---|---|---|---|
C15 | 0.038 | 19.45 | 0.96 |
C20 | 0.037 | 22.27 | 0.90 |
C30 | 0.052 | 24.27 | 0.89 |
Water Saturation Si/% | Predicted Value by Equation (4) Elasticity Modulus/GPa | Tested Value Reference [19] Elasticity Modulus/GPa | Relative Error/% |
---|---|---|---|
0.00 | 24.27 | 25.01 | −2.97 |
35.14 | 26.10 | 27.59 | −5.42 |
75.68 | 28.21 | 29.82 | −5.42 |
72.97 | 28.06 | 29.80 | −5.81 |
100.00 | 29.47 | 32.47 | −9.23 |
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Zhang, G.; Li, C.; Wei, H.; Wang, M.; Yang, Z.; Gu, Y. Influence of Humidity on the Elastic Modulus and Axis Compressive Strength of Concrete in a Water Environment. Materials 2020, 13, 5696. https://doi.org/10.3390/ma13245696
Zhang G, Li C, Wei H, Wang M, Yang Z, Gu Y. Influence of Humidity on the Elastic Modulus and Axis Compressive Strength of Concrete in a Water Environment. Materials. 2020; 13(24):5696. https://doi.org/10.3390/ma13245696
Chicago/Turabian StyleZhang, Guohui, Changbing Li, Hai Wei, Mingming Wang, Zhendong Yang, and Yanshuang Gu. 2020. "Influence of Humidity on the Elastic Modulus and Axis Compressive Strength of Concrete in a Water Environment" Materials 13, no. 24: 5696. https://doi.org/10.3390/ma13245696
APA StyleZhang, G., Li, C., Wei, H., Wang, M., Yang, Z., & Gu, Y. (2020). Influence of Humidity on the Elastic Modulus and Axis Compressive Strength of Concrete in a Water Environment. Materials, 13(24), 5696. https://doi.org/10.3390/ma13245696