Your search keyword '"Xinglong Zhao"' showing total 2 results

1. Using hydraulic fracturing to control caving of the hanging roof during the initial mining stages in a longwall coal mine: a case study

Author

Xinglong Zhao, Malcolm Scoble, Qingying Cheng, Weichao Xue, and Bingxiang Huang

Subjects

Drill, business.industry, Coal mining, Fracture mechanics, 02 engineering and technology, Fracture plane, 010502 geochemistry & geophysics, 01 natural sciences, Cave-in, 020501 mining & metallurgy, Hydraulic fracturing, 0205 materials engineering, Mining engineering, General Earth and Planetary Sciences, Coal, business, Roof, Geology, 0105 earth and related environmental sciences, General Environmental Science

Abstract

Hanging roofs can occur on a very large scale (generally can reach 15,000 m2) during the initial mining stages in longwall coal mining operations and are often a result of hard roof at the active mining face. Besides, when it suddenly fractures and caves, some risks and disasters would occur such as shock loading, wind blasts, and sudden gas extrusion from gob to working face. To control the size and competency of the hanging roof, Φ32-mm fracturing drills can create holes in the roof near the front and back coal walls, and Φ32-mm linear fracturing drills can be used to create holes in the roof at the face ends. The length of these drill holes is 3 to 5 times the height of the mining face and is based upon the principle that the gob should be fully filled with a caved roof to support vertical stresses, as well as the assumption that the broken-expansion coefficient of the rock is given as an empirical value. Considering the fracture propagation range and the support form of the cut, the drill-hole spacing is set to be between 1 and 2 times the single-hole crack propagation range. Hydraulic fracturing can generate main fractures and wing-shaped branching cracks inside the roof rock and can transform and weaken the roof structure, forming weak fracture plane favorable to roof caving. These fractures cause the roof to cave in a timely and adequate manner under in situ ground pressures. Successful field test in the no. 2 mine of Cuncaota, Shendong group indicated that the propagation range of hydraulic fractures is approximately 4–8 m. When the active face advanced 22.5 m, the roof beyond the hydraulic supports caves entirely, and gradually, the gob is fully filled with the caved roof and is absent of large voids. Thus, hazards such as shock loading, wind blasts, and sudden gas extrusion can be reduced or eliminated.

Published

2018

2. Hydraulic fracturing stress transfer methods to control the strong strata behaviours in gob-side gateroads of longwall mines

Author

Bingxiang Huang, Shuliang Chen, and Xinglong Zhao

Subjects

business.industry, 0211 other engineering and technologies, Coal mining, Abutment, 02 engineering and technology, Field tests, 020501 mining & metallurgy, Stress (mechanics), Hydraulic fracturing, 0205 materials engineering, Mining engineering, General Earth and Planetary Sciences, Longwall mining, Geotechnical engineering, Extraction (military), business, Roof, Geology, 021101 geological & geomatics engineering, General Environmental Science

Abstract

With hard roof conditions and the influence of side and front abutment pressures, pressure bump and large deformations periodically occur in the advanced support area of longwall face gob-side gateroads. To control the strong strata behaviours in gob-side gateroads, “directional hydraulic fracturing, to cut off the roof hanging over the adjacent gob area, and pre-fracturing of the roof, located behind the working face being extracted,” are performed. The directional initiation of hydraulic fracturing is controlled by pre-slotting, and this action guides the propagation of hydraulic fractures in three-dimensional space. The oriented fractures meet engineering requirements by cooperating with both the in situ ground stresses and the mining-induced stresses, as well as the technology of hydraulic fracturing. In field applications, hydraulic fracturing has proven to be a viable option for weakening hard roofs, destressing the side and front abutment pressures at the mining face and also transferring in situ and mining-induced stresses. Successful field tests in the Tongxin coal mine, Datong district, as well as other coal mines, show that hydraulic fracturing in both a hanging roof over an adjacent gob area and in the gob area behind the advancing working face controls the behaviour of strong strata material on the gob-side of gateroads in longwall mining and also guarantees safe extraction at the working face.

Published

2017