Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum

Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum

In the process of coal seam mining, there are often hard thick key layers in the overlying strata. Due to the high strength and good integrity of the hard thick key layer, after the hard thick key layer is broken, the overlying strata will collapse and lose stability in a large area, which is very e...

Full description

Saved in:
Bibliographic Details
Main Authors: Kaihua Liang, Quansen Wu, Quanlin Wu, Xiang Shi, Hong Zhao, Fuwu Ma, Zhaomin Zhang
Format: Article
Language:English
Published: Wiley 2023-01-01
Series:Geofluids
Online Access:http://dx.doi.org/10.1155/2023/1750844
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1849396615788363776
author Kaihua Liang
Quansen Wu
Quanlin Wu
Xiang Shi
Hong Zhao
Fuwu Ma
Zhaomin Zhang
author_facet Kaihua Liang
Quansen Wu
Quanlin Wu
Xiang Shi
Hong Zhao
Fuwu Ma
Zhaomin Zhang
author_sort Kaihua Liang
collection DOAJ
description In the process of coal seam mining, there are often hard thick key layers in the overlying strata. Due to the high strength and good integrity of the hard thick key layer, after the hard thick key layer is broken, the overlying strata will collapse and lose stability in a large area, which is very easy to induce dynamic disasters such as rock burst, mine earthquake, coal wall caving, and roof slab caving. Aiming at the hard and thick key layer overlying the working face, the dynamic response of the mine under the strong mine earthquake induced by the breaking of the main key layer of high-level magmatic rock is numerically simulated and analyzed by using FLAC2D numerical simulation software, and the variation laws of the stress field, displacement field, and velocity field of the coal seam roadway under different boundary conditions and different focal heights are studied. The research shows that the roof of solid coal roadway is prone to vibration in a small range, and the displacement increases and decreases with the disturbance. The displacement of the floor and two sides of the solid coal roadway and the top floor and two sides of the roadway along the goaf continues to increase in the initial stage of the disturbance, and the displacement will remain stable with the continuation of the disturbance. The displacement of both sides and roof and floor of gob roadway can reach stability in the later stage of disturbance, and with the increase of the number of adjacent goaf, the longer it takes for the displacement of surrounding rock to reach stability. When the focal height is lower than 90 m, the variation of surrounding rock response increases sharply with the decrease of focal height. When a strong earthquake occurs in the low rock stratum, the impact damage of roadway surrounding rock is almost inevitable. The influence degree of strong earthquake on the stability of roadway surrounding rock is arranged as follows: gob-side roadway (mined out on one side) > solid coal roadway (mined out on both sides) > solid coal roadway (mined out on one side). The evolution process also shows that the working face boundary conditions have an important influence on the energy propagation of mine earthquake. With the increase of the number of adjacent goafs, the faster the energy attenuation rate of mine earthquake propagation is. The research results have important reference significance for the safe mining of working face under similar geological conditions.
format Article
id doaj-art-b05306d3beb14eefa177d712bb3cd796
institution Kabale University
issn 1468-8123
language English
publishDate 2023-01-01
publisher Wiley
record_format Article
series Geofluids
spelling doaj-art-b05306d3beb14eefa177d712bb3cd7962025-08-20T03:39:17ZengWileyGeofluids1468-81232023-01-01202310.1155/2023/1750844Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock StratumKaihua Liang0Quansen Wu1Quanlin Wu2Xiang Shi3Hong Zhao4Fuwu Ma5Zhaomin Zhang6Engineering Laboratory of Deep Mine Rockburst Disaster AssessmentJining UniversityJining UniversityEngineering Laboratory of Deep Mine Rockburst Disaster AssessmentEngineering Laboratory of Deep Mine Rockburst Disaster AssessmentEngineering Laboratory of Deep Mine Rockburst Disaster AssessmentEngineering Laboratory of Deep Mine Rockburst Disaster AssessmentIn the process of coal seam mining, there are often hard thick key layers in the overlying strata. Due to the high strength and good integrity of the hard thick key layer, after the hard thick key layer is broken, the overlying strata will collapse and lose stability in a large area, which is very easy to induce dynamic disasters such as rock burst, mine earthquake, coal wall caving, and roof slab caving. Aiming at the hard and thick key layer overlying the working face, the dynamic response of the mine under the strong mine earthquake induced by the breaking of the main key layer of high-level magmatic rock is numerically simulated and analyzed by using FLAC2D numerical simulation software, and the variation laws of the stress field, displacement field, and velocity field of the coal seam roadway under different boundary conditions and different focal heights are studied. The research shows that the roof of solid coal roadway is prone to vibration in a small range, and the displacement increases and decreases with the disturbance. The displacement of the floor and two sides of the solid coal roadway and the top floor and two sides of the roadway along the goaf continues to increase in the initial stage of the disturbance, and the displacement will remain stable with the continuation of the disturbance. The displacement of both sides and roof and floor of gob roadway can reach stability in the later stage of disturbance, and with the increase of the number of adjacent goaf, the longer it takes for the displacement of surrounding rock to reach stability. When the focal height is lower than 90 m, the variation of surrounding rock response increases sharply with the decrease of focal height. When a strong earthquake occurs in the low rock stratum, the impact damage of roadway surrounding rock is almost inevitable. The influence degree of strong earthquake on the stability of roadway surrounding rock is arranged as follows: gob-side roadway (mined out on one side) > solid coal roadway (mined out on both sides) > solid coal roadway (mined out on one side). The evolution process also shows that the working face boundary conditions have an important influence on the energy propagation of mine earthquake. With the increase of the number of adjacent goafs, the faster the energy attenuation rate of mine earthquake propagation is. The research results have important reference significance for the safe mining of working face under similar geological conditions.http://dx.doi.org/10.1155/2023/1750844
spellingShingle Kaihua Liang
Quansen Wu
Quanlin Wu
Xiang Shi
Hong Zhao
Fuwu Ma
Zhaomin Zhang
Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum
Geofluids
title Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum
title_full Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum
title_fullStr Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum
title_full_unstemmed Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum
title_short Dynamic Response Analysis of Roadway Surrounding Rock Induced by Dynamic Load under the Action of Hard and Thick Rock Stratum
title_sort dynamic response analysis of roadway surrounding rock induced by dynamic load under the action of hard and thick rock stratum
url http://dx.doi.org/10.1155/2023/1750844
work_keys_str_mv AT kaihualiang dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum
AT quansenwu dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum
AT quanlinwu dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum
AT xiangshi dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum
AT hongzhao dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum
AT fuwuma dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum
AT zhaominzhang dynamicresponseanalysisofroadwaysurroundingrockinducedbydynamicloadundertheactionofhardandthickrockstratum

Similar Items