Investigation of the mechanical behaviour of concrete with severe delayed ettringite formation expansion focusing on internal damage propagation under various compressive loading patterns

“…Larger strains formed on the axial sides of the coarse aggregates. In addition, the tensile principal strains were generated at lateral sides of the aggregate interface, as well as in the mortar with the expansion of 1.7% at 114 and 217 d. These strain distribution results were consistent with the previous studies (Joshi et al 2022;Miura et al 2022).…”

“…The strains at the compressive strength of stepwise cyclic and sustained loadings were approximately 7000 microstrains for the expansion of 1.7% at 217 d, which is larger than that of monotonic loading. This trend is also consistent with Joshi et al (2022). Nevertheless, the compressive strength and softening gradient exhibited the same trends as those of monotonic loading.…”

“…Specifically, the strain at compressive strength was 6300 microstrains for the expansion of 1.7% at 217 d, which is more than twice that of control specimens (2600 microstrains). Joshi et al (2022) also confirmed that the strain at compressive strength was 6200 microstrains for the expansion of 2.4%. In stepwise cyclic and sustained loadings, for the expansion of 0.6%, the large ε cyc_25 and ε sus_25 were generated even at the stress level of 25%, which generally corresponds to elastic stage of normal concrete.…”

“…However, the corresponding values did not directly relate to the reduction in mechanical properties based on the crack information. Joshi et al (2022) assessed internal crack behavior of concrete damaged severely by DEF during compressive loading. They applied various loading histories to concrete damaged by DEF with a high expansion level and observed the internal crack behavior during compressive loading using micro-X-ray CT scanning.…”

Stress-bearing Mechanism of Concrete Damaged by Delayed Ettringite Formation under Compressive Stress with Various Loading Patterns

“…Larger strains formed on the axial sides of the coarse aggregates. In addition, the tensile principal strains were generated at lateral sides of the aggregate interface, as well as in the mortar with the expansion of 1.7% at 114 and 217 d. These strain distribution results were consistent with the previous studies (Joshi et al 2022;Miura et al 2022).…”

“…The strains at the compressive strength of stepwise cyclic and sustained loadings were approximately 7000 microstrains for the expansion of 1.7% at 217 d, which is larger than that of monotonic loading. This trend is also consistent with Joshi et al (2022). Nevertheless, the compressive strength and softening gradient exhibited the same trends as those of monotonic loading.…”

“…Specifically, the strain at compressive strength was 6300 microstrains for the expansion of 1.7% at 217 d, which is more than twice that of control specimens (2600 microstrains). Joshi et al (2022) also confirmed that the strain at compressive strength was 6200 microstrains for the expansion of 2.4%. In stepwise cyclic and sustained loadings, for the expansion of 0.6%, the large ε cyc_25 and ε sus_25 were generated even at the stress level of 25%, which generally corresponds to elastic stage of normal concrete.…”

“…However, the corresponding values did not directly relate to the reduction in mechanical properties based on the crack information. Joshi et al (2022) assessed internal crack behavior of concrete damaged severely by DEF during compressive loading. They applied various loading histories to concrete damaged by DEF with a high expansion level and observed the internal crack behavior during compressive loading using micro-X-ray CT scanning.…”

Stress-bearing Mechanism of Concrete Damaged by Delayed Ettringite Formation under Compressive Stress with Various Loading Patterns

“…Xi măng đóng vai trò tăng cường cường độ CKD thạch cao hai thành phần, mức tăng cường độ tùy thuộc vào tỷ lệ giữa các sản phẩm hydrat hóa gel C-S-H và ettringite trong hỗn hợp CKD. Với hàm lượng xi măng tăng cao có thể dẫn đến việc tạo ra các sản phẩm có quá nhiều alumin canxi với cường độ thấp do cấu trúc bên trong có nhiều khuyết tật và thậm chí tạo ra các vết nứt vi mô cho nên cường độ CKD tăng chậm hoặc giảm [28], [29]. Từ kết quả trên Hình 6 cho thấy khi phối hợp sử dụng xi măng và MK trong CKD đã cải thiện rõ rệt cường độ nén (cường độ nén ở trạng thái khô đạt 25,0÷41,1 MPa và ở trạng thái bão hòa đạt 19,2÷38,2 MPa) và nâng cao đáng kể hệ số hóa mềm lên 0,77÷0,93.…”

Chất kết dính thạch cao hỗn hợp cường độ cao, bền nước trên cơ sở thạch cao FGD-xi măng poóc lăng và mê ta cao lanh

A new accelerated testing scheme to evaluate the potential oxidation reaction of sulfide-bearing aggregates in concrete specimens