Yong Luo scite author profile

In order to investigate the high loading rate effect on the behaviour and mechanical properties of coal-rock combined body, the dynamic compressive tests were conducted by using the Split-Hopkinson Pressure Bar (SHPB) device under the loading rate range from 2.7×10 5 MPa/s to 4.0×10 5 MPa/s. The stress-strain curves, dynamic peak stress and strain, elastic modulus, and energy distribution law of coal-rock combined body under different loading rates were analyzed and discussed. The results show that the dynamic stress-strain curves of coal-rock combined body have a double-peak feature under high loading rate range, which can be divided into the initial bearing stage, the bearing decline stage, the bearing enhance stage, and the unstable stage. The first peak stress of the coal-rock combined body is independent of the loading rate, while the dynamic compressive strength (the second peak stress) and dynamic peak strain (the second peak strain) have a strong loading rate effect and will generally increase linearly with the loading rate. The first and second elastic moduli of coal-rock combined body are not sensitive to the loading rate. With the increase of the loading rate, the incident energy and reflective energy of coal-rock combined body increase rapidly, while the change of transmitted energy is very small. The absorption energy ratio of the coal-rock combined body shows a good linear law with the incident energy under different loading rates.

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Cobalt phosphide microsphere as an efficient bifunctional oxygen catalyst for Li-air batteries

Zhang

Wei

Sui

et al. 2018

Journal of Alloys and Compounds

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Yong Luo

In situ preparation of hollow Mo₂C–C hybrid microspheres as bifunctional electrocatalysts for oxygen reduction and evolution reactions

Experimental simulation investigation on rockburst induced by spalling failure in deep circular tunnels

NiCo2O4@La0.8Sr0.2MnO3 core–shell structured nanorods as efficient electrocatalyst for Li O2 battery with enhanced performances

The Effect of High Loading Rate on the Behaviour and Mechanical Properties of Coal‐Rock Combined Body

Cobalt phosphide microsphere as an efficient bifunctional oxygen catalyst for Li-air batteries

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Yong Luo

In situ preparation of hollow Mo2C–C hybrid microspheres as bifunctional electrocatalysts for oxygen reduction and evolution reactions

Experimental simulation investigation on rockburst induced by spalling failure in deep circular tunnels

NiCo2O4@La0.8Sr0.2MnO3 core–shell structured nanorods as efficient electrocatalyst for Li O2 battery with enhanced performances

The Effect of High Loading Rate on the Behaviour and Mechanical Properties of Coal‐Rock Combined Body

Cobalt phosphide microsphere as an efficient bifunctional oxygen catalyst for Li-air batteries

Contact Info

Product

Resources

About

In situ preparation of hollow Mo₂C–C hybrid microspheres as bifunctional electrocatalysts for oxygen reduction and evolution reactions