What question did this study set out to answer?

This research aims to improve roof cutting methods for hard key strata in gob-side entry retaining. The focus is on enhancing pressure relief while ensuring safety during mining operations.

April 12, 2026Open Access

Application of High-Pressure Water-Jet Slotting and Pre-Cracked Weakening Belt Technology in Gob-Side Entry Retaining for Roof Cutting and Pressure Relief

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This research aims to improve roof cutting methods for hard key strata in gob-side entry retaining. The focus is on enhancing pressure relief while ensuring safety during mining operations.
Proposed high-pressure water-jet slotting-induced pre-cracked weakening belt technology.
Utilized finite-length weakening belts arranged to create a preferred failure path.
Conducted two-dimensional RFPA2D simulations to optimize weakening belt geometry.
Performed high-pressure water-jet tests on limestone blocks to assess penetration and crack behavior.
Field application conducted at Dongjiang Mine to evaluate practical effectiveness.
Induced bending and shear stresses increased by 1.5–2.8 times and 1.2–1.7 times, respectively, in the key strata.
Achieved optimal weakening belt dimensions of 400 mm width and 200 mm length.
Intra-pair spacing of approximately 40 mm yielded a continuous weakening belt, enhancing performance.
Field tests showed improvement in mining conditions with earlier weighting and reduced support resistance.

Resumen

To address the difficulty of directionally cutting thick, hard key strata in gob-side entry retaining using conventional blasting or hydraulic fracturing, this paper proposes a high-pressure water-jet slotting-induced pre-cracked weakening belt (PCWB) roof-cutting technology. Several finite-length PCWBs are arranged within the key stratum and designed to coalesce into a plane, inducing through-going roof failure along a pre-determined path. A fixed–fixed key strata beam model combined with linear elastic fracture mechanics shows that the double-belt configuration forces the bending moment and shear force to concentrate in a thin rock bridge, where bending and shear stresses are amplified by about 1.5–2.8 times and 1.2–1.7 times, respectively, for 2–4 m thick key strata, providing a mechanical basis for preferential tensile–shear failure. Two-dimensional RFPA2D simulations reveal “width-dominated, length-assisted” control of cutting performance and identify an optimal weakening belt geometry of about 400 mm in width and 200 mm in length. Three-dimensional numerical modeling of parallel slot pairs indicates that intra-pair spacing of about 40 mm produces a continuous, directional weakening belt, whereas smaller or larger spacing causes, respectively, destructive interference or loss of connectivity. High-pressure water-jet tests (320 MPa, 0.33 mm nozzle, 1.30 mm/s traverse speed) on limestone blocks confirm that single slots can penetrate the full thickness and that cracks from adjacent slots coalesce through the rock bridge, forming a wide, straight fracture band. Field application in the Dongjiang Mine (3.5 m limestone key stratum, ~400 m depth) shows that the first weighting is advanced from the 7th to the 3rd day, peak support resistance is reduced from 8.8 to 7.4 MPa, and periodic weighting becomes more frequent and smoother. The PCWB technology is therefore suitable for panels with 2–4 m thick hard key strata at similar depths, offering precise key stratum severance, active stress relief, and safe, controllable construction.

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