Compaction Characteristics and Size Effects of Soft Rock Rockfill

ZHAO Na; ZUO Yong-zhen; LU Shi-quan; ZHOU Yue-feng; ZHANG Ting

doi:10.11988/ckyyb.20230644

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Journal of Changjiang River Scientific Research Institute ›› 2024, Vol. 41 ›› Issue (11) : 158-162. DOI: 10.11988/ckyyb.20230644

Rock-Soil Engineering

Compaction Characteristics and Size Effects of Soft Rock Rockfill

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Abstract

The dry density of soft rock rockfill is an important control index for the design and construction of earth-rock dams, as it directly influences the settlement of earth-rock dams during construction and operation. The Φ950 mm×H1 000 mm super-large compactor was used to conduct compaction tests under five levels of compaction energy, including 483, 992, 1 475, 1 957,2 681 kJ/m³, for the strongly weathered silty mudstone, weakly weathered silty mudstone,and a mixture of silty mudstone. The results were compared with those from φ300 mm×H285 mm large compaction test. The test results show that the dry density increases with the increase in compaction energy.When the compaction energy is less than 2 000 kJ/m³, the dry density increases rapidly with increasing the compaction energy. When the compaction energy exceeds 2 000 kJ/m³, the rate of increase slows down and the increment is small. Further increasing the compaction energy does not significantly improve the dry density.Under the same compaction energy, the maximum dry density from the ultra-large compaction is slightly lower (by 0.01 to 0.02 g/cm³) than that from the large compaction test. The size effect of soft rock rockfill on compaction characteristics is not significant, and under the heavy standard compaction functional conditions, it is appropriate to use a compaction instrument with a diameter of 300 mm to study the compaction characteristics of soft rock rockfill indoors.

Key words

soft rock rockfill / super-large compaction instrument / dry density / compaction energy / size effect / particle crushing rate

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ZHAO Na , ZUO Yong-zhen , LU Shi-quan , et al . Compaction Characteristics and Size Effects of Soft Rock Rockfill[J]. Journal of Yangtze River Scientific Research Institute. 2024, 41(11): 158-162 https://doi.org/10.11988/ckyyb.20230644

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In this article, the mechanical behavior of soft rock filling material for dam construction before and after degradation is investigated through laboratory tests at different consolidation pressures and compaction degrees. The degradation in strength and deformation characteristics of the rockfill material is analyzed. The relationship between degree of compaction and normalized strength, and the relationship between degree of compaction and normalized deformation modulus are built respectively. The controlling degree of compaction is also given for construction. Furthermore, according to results from underwater test of repose angle, the nonlinear strength, in particular, the strength at low stress state is studied. Research findings conclude that the degradation leads to the decline of volume strain,and poses larger impact on deformation modulus than strength;a 96% degree of compaction is reasonable for <br/>soft rock filling material as it ensures a normalized strength larger than 0.9 and normalized deformation modulus larger than 0.8, and guarantees the compaction efficiency as well. Moreover, the strength parameters of soft rock filling material can be acquired from underwater repose angle test on compacted samples; and the nonlinear strength can be obtained through triaxial test. The research findings can be utilized to evaluating the stress-strain rules of rockfill dam built in soft rock and to providing guidance for dam construction.

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