ORGANIZATION OF ENSURING THE SAFETY OF PRODUCTION PROCESSES IN A COAL MINE IN THE FACE OF AN INCREASE IN THE CAPACITY OF MINING EQUIPMENT

To improve the efficiency of the mining industry, it is necessary to coordinate all production processes, which allows reducing unproductive downtime of mining and transport equipment, increasing their productivity, and reducing the cost of operations at all stages of the production cycle. To achieve this result, the article uses a systematic approach to consider the features of planning the work of all departments of the coal mine, starting with drilling and blasting operations on the sites and ending with the shipment of finished products to consumers. Based on the example of JSC “Chernigovets” in the Kemerovo region, the article considers a two-level model for planning the work of all divisions of the enterprise for a month, taking into account the dynamics of resource use of production and transport sections. Taking into account the uneven performance of production operations and the wide variety of mining equipment used at the stages of preparation, excavation, excavation, transportation, processing and shipment of finished products to external rail transport, it is possible to use a hierarchical two-level system with aggregation of processes at the first level and their detail at the second level. Using the dynamic programming method allowed us to solve the problem of planning the activities of all divisions of the enterprise at the first level and identify the boundaries of changes in the planned indicators at the second level, which do not worsen the results achieved at the first level. The proposed method of planning the operation of the mine will allow you to quickly track the achieved indicators, compare them with the planned ones and, if necessary, adjust the work of the enterprise’s divisions in real time to achieve the best performance indicators of the coal mine as a whole.

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Directional Hydraulic Fracturing (DHF) of the Roof, as an Element of Rock Burst Prevention in the Light of Underground Observations and Numerical Modelling

Energies ◽

10.3390/en14030562 ◽

2021 ◽

Vol 14 (3) ◽

pp. 562

Author(s):

Marek Jendryś ◽

Andrzej Hadam ◽

Mateusz Ćwiękała

Keyword(s):

Rock Mass ◽

Hydraulic Fracturing ◽

Coal Mining ◽

Rock Burst ◽

Coal Mine ◽

Seismic Activity ◽

Black Coal ◽

Directional Hydraulic Fracturing ◽

Before And After ◽

The Face

The following article analyzes the effectiveness of directional hydraulic fracturing (DHF) as a method of rock burst prevention, used in black coal mining with a longwall system. In order to define changes in seismic activity due to DHF at the “Rydułtowy” Black Coal Mine (Upper Silesia, Poland), observations were made regarding the seismic activity of the rock mass during coal mining with a longwall system using roof layers collapse. The seismic activity was recorded in the area of the longwall itself, where, on a part of the runway, the rock mass was expanded before the face of the wall by interrupting the continuity of the rock layers using DHF. The following article presents measurements in the form of the number and the shock energy in the area of the observed longwall, which took place before and after the use of DHF. The second part of the article unveils the results of numerical modeling using the discrete element method, allowing to track the formation of goafs for the variant that does not take DHF into consideration, as well as with modeled fractures tracing DHF carried out in accordance with the technology used at “Rydułtowy” coal mine.

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Talking about the Damage Analysis and Processing Technology Improvement Method of a Coal Mining Equipment Walking Mechanism in Shendong Coal Mine

2020 International Conference on Artificial Intelligence and Electromechanical Automation (AIEA) ◽

10.1109/aiea51086.2020.00127 ◽

2020 ◽

Author(s):

Zhi Li ◽

Xiaolong Liu

Keyword(s):

Coal Mining ◽

Coal Mine ◽

Processing Technology ◽

Damage Analysis ◽

Mining Equipment ◽

Technology Improvement ◽

Improvement Method ◽

Walking Mechanism

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Failure Mechanisms and the Control of a Longwall Face with a Large Mining Height within a Shallow-Buried Coal Seam

Shock and Vibration ◽

10.1155/2021/8494913 ◽

2021 ◽

Vol 2021 ◽

pp. 1-11

Author(s):

Haijun Wang ◽

Yingjie Liu ◽

Yuesong Tang ◽

Hao Gong ◽

Guoliang Xu

Keyword(s):

Tensile Stress ◽

Coal Mine ◽

Horizontal Displacement ◽

Longwall Face ◽

Mining Equipment ◽

Coal Seams ◽

Increasing Trend ◽

Support Force ◽

Coal Wall ◽

Mining Height

The capabilities of mining equipment and technology in China have been improving rapidly in recent years. Correspondingly, in the western part of the country, the mining heights of longwall faces in shallow-buried coal seams have shown an increasing trend, resulting in enhanced mining efficiency. However, the problems associated with the possible failure of the coal wall then increase and remain a serious difficulty, restricting safe and efficient mining operations. In the present study, the 12401 longwall face of the Shangwan Coal Mine, Inner Mongolia, China, with a mining height of 8.8 m, is taken as an example to study the mechanisms underlying failure phenomena of coal walls and their control methods. Our results show that the failure region inward of the longwall face is small in shallow-buried coal seams, and the damage degree of the exposed coal wall is low. The medium and higher sections of the coal wall display a dynamic failure mode, while the broken coal blocks, given their initial speed, threaten the safety of coal miners. A mechanical model was developed, from which the conditions for tensile failure and structural instability are deduced. Horizontal displacement in the lower part of the coal wall is small, where no tensile stress emerges. On the other hand, in the intermediate and higher parts of the coal wall, horizontal displacement is relatively large. In addition, tensile stress increases first with increasing distance from the floor and then decreases to zero. Experiments using physical models representing different mining heights have been carried out and showed that the horizontal displacement increases from 6 to 12 mm and load-bearing capacity decreases from 20 to 7.9 kN when the coal wall increases in height from 3 to 9 m. Furthermore, failure depth and failure height show an increasing trend. It is therefore proposed that a large initial support force, large maximum support force, large support stiffness, and large support height of a coal wall-protecting guard are required for the improved stability of high coal walls, which operate well in the Shangwan coal mine.

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Cognitive Control Technology for a Self-Optimizing Robot Based Assembly Cell

Volume 3: 28th Computers and Information in Engineering Conference, Parts A and B ◽

10.1115/detc2008-49521 ◽

2008 ◽

Cited By ~ 5

Author(s):

Christian Brecher ◽

Tobias Kempf ◽

Werner Herfs

Keyword(s):

Cognitive Control ◽

Production Systems ◽

Research Approach ◽

Labor Costs ◽

Automated Production ◽

Production Processes ◽

Assembly Cell ◽

The Face ◽

Planning Orientation ◽

Automation Technology

In the face of global competition there is a great danger for countries with high labor costs (e.g. Germany) to lose more and more production plants to low-wage countries. Almost inevitably there will be a relocation of after-sales services as well as of research and development. Eventually this will cause a significant decline of wealth. For this reason especially high-wage countries are always striving for higher productivity of production processes. On the other hand the products have to be of high-end quality to ensure an advantage in the market. Thus there is an obvious dilemma between planning-orientation and value-orientation which has to be resolved. This could possibly be obtained by shifting planning efforts to the runtime system and at the same time enabling the system to adapt to changing requests and circumstances. In order to get there, automation technology is definitely playing a key role in present-day highly automated production processes. Unfortunately classical automation technology has not been supporting this kind of self-organizing, self-controlling and self-optimizing behavior. This paper introduces an approach to make production systems more “intelligent” based on the idea of a cognitive control architecture. At first the motivation and the research vision are introduced followed by an outline of the research approach. As a concrete example of an application a robot based assembly cell is described. The methods used and insights gained so far are presented in the second part, followed by an outlook towards future activities.

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Research on Underground Coal Mine Production Process Analysis and Informatization

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.171-172.278 ◽

2010 ◽

Vol 171-172 ◽

pp. 278-282 ◽

Cited By ~ 1

Author(s):

Jin Feng Wang ◽

Li Jie Feng ◽

Zhen Zhao ◽

Hua Jie Yu

Keyword(s):

Information System ◽

Production Process ◽

Coal Mine ◽

Process Analysis ◽

Underground Coal Mine ◽

Continuous Type ◽

Production Processes ◽

Mine Production ◽

Discrete Type

This article analyzes the characteristics of underground coal mine production process, and compares underground coal mine production process with discrete type and continuous type production processes. On this basis, it investigates the construction and implementation countermeasures on underground coal mine information system.

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Network Performance Comparison between Linear and Hybrid Topology Structure of WSN in Coal Mining Equipment

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.548.775 ◽

2012 ◽

Vol 548 ◽

pp. 775-779

Author(s):

Hong Liang Gao ◽

Bing Wen Wang ◽

Chao Gao ◽

Xiao Ya Hu

Keyword(s):

Coal Mine ◽

Packet Loss ◽

Network Performance ◽

Loss Rate ◽

Packet Loss Rate ◽

Mine Safety ◽

Mining Equipment ◽

Linear Topology ◽

Hybrid Topology ◽

Average Transmission

This paper analyzes the characteristics of current monitoring wireless sensor networks for coal mine safety and two kinds of typical system network architecture of mining working face in coal mine firstly, and then analyzes the network performance of the two kinds of network system theoretically. In order to compare the performance of WSN adopting linear topology and hybrid topology, we build the simulation model using NS2 to evaluate the performance through three indexes, i.e. total energy consumption, packet loss rate and average transmission latency. The research results show that the network adopting hybrid topology has better energy efficiency, and the network adopting linear topology has better performance in packet loss rate and average transmission latency.

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A Coal Mine Hydraulic Support Design and Type Selection of Medium Thick Coal Seam

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.633-634.1128 ◽

2014 ◽

Vol 633-634 ◽

pp. 1128-1132

Author(s):

Li Rong Zhang

Keyword(s):

Coal Seam ◽

Coal Mine ◽

Simulation Method ◽

Bottom Plate ◽

Mining Equipment ◽

Hydraulic Support ◽

Support Design ◽

Thick Coal Seam ◽

Technical Parameters ◽

Selection Of

Design and selection of hydraulic support is the core of coal mine fully mechanized mining equipment selection and matching, determine the hydraulic supporting strength Using the numerical simulation method and shallow buried depth of roof structure of theoretical calculation method, determines the necessary technical parameters such as the support frame, the bracket height and the bottom plate pressure According to the coal seam thickness and coal seam structure, which has the instructive meaning in application.

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Modeling Rock Fracture Propagation and Water Inrush Mechanisms in Underground Coal Mine

Geofluids ◽

10.1155/2019/1796965 ◽

2019 ◽

Vol 2019 ◽

pp. 1-15 ◽

Cited By ~ 6

Author(s):

Shichuan Zhang ◽

Baotang Shen ◽

Yangyang Li ◽

Shengfan Zhou

Keyword(s):

Coal Seam ◽

Coal Mine ◽

Rock Fracture ◽

Water Inrush ◽

Water Channel ◽

Karst Collapse ◽

Mining Equipment ◽

Geological Conditions ◽

Fracturing Process ◽

Collapse Column

Water inrush in underground mines is a major safety threat for mining personnel, and it can also cause major damage to mining equipment and result in severe production losses. Water inrush can be attributed to the coalescence of rock fractures and the formation of water channel in rock mass due to the interaction of fractures, hydraulic flow, and stress field. Hence, predicting the fracturing process is the key for investigating the water inrush mechanisms for safe mining. A new coupling method is designed in FRACOD to investigate the mechanisms of water inrush disaster (known as “Luotuoshan accident”) which occurred in China in 2010 in which 32 people died. In order to investigate the evolution processes and mechanisms of water inrush accident in Luotuoshan coal mine, this study applies the recently developed fracture-hydraulic (F-H) flow coupling function to FRACOD and focuses on the rock fracturing processes in a karst collapse column which is a geologically altered zone linking several rock strata vertically formed by the long-term dissolution of the flowing groundwater. The numerical simulation of water inrush is conducted based on the actual geological conditions of Luotuoshan mining area, and various materials with actual geological characteristics were used to simulate the rocks surrounding the coal seam. The influences of several key factors, such as in situ stresses, fractures on the formation, and development of water inrush channels, are investigated. The results indicate that the water inrush source is the Ordovician limestone aquifer, which is connected by the karst collapse column to No. 16 coal seam; the fracturing zone that led to a water inrush occurs in front of the roadway excavation face where new fractures coalesced with the main fractured zone in the karst collapse column.

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Development Of Software To Evaluate Roof Fall Risk In Bord And Pillar Method - Depillaring Phase

GeoScience Engineering ◽

10.1515/gse-2015-0014 ◽

2015 ◽

Vol 61 (2) ◽

pp. 14-22 ◽

Cited By ~ 1

Author(s):

Devidas S. Nimaje ◽

Shiva Sai

Keyword(s):

Coal Mine ◽

Fall Risk ◽

Coal Mines ◽

Mining Equipment ◽

Underground Coal Mine ◽

Company Limited ◽

Roof Fall ◽

Considerable Damage

Abstract Roof fall is one of the major problems of the bord and pillar coal mines during the depillaring phase. Roof fall not only causes considerable damage to the mining equipment but also to the miners. To keep in view, development of software is essential for the calculation of roof fall risk to reduce the accidents to a certain extent. In this paper, the software has been developed and tested on seam-2, the main panel of RK-5 underground coal mine, Singareni Collieries Company Limited, India and corresponding roof fall risk was calculated. The best combination of the parameters causing roof fall risk was evaluated to reduce the risk.

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