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Engineering, Technology & Applied Science Research Vol. 6, No. 3, 2016, 993-999 993  
  

www.etasr.com Okolnishnikov et al.: Simulating the Various Subsystems of a Coal Mine

 

Simulating the Various Subsystems of a Coal Mine 
 

Victor Okolnishnikov 
Siberian Branch of the Russian 

Academy of Sciences  
Design Technological Institute of 

Digital Techniques 
Novosibirsk, Russia 

okoln@mail.ru 

Sergey Rudometov 
Siberian Branch of the Russian 

Academy of Sciences  
Design Technological Institute of 

Digital Techniques 
Novosibirsk, Russia 

rsw@academ.org 
 

Sergey Zhuravlev 
Siberian Branch of the Russian 

Academy of Sciences  
Design Technological Institute of 

Digital Techniques 
Novosibirsk, Russia 
s-zhur@yandex.ru 

 
 

 

Abstract—A set of simulation models of various subsystems of a 
coal mine was developed with the help of a new visual interactive 
simulation system of technological processes. This paper contains 
a brief description of this simulation system and its possibilities. 
The main possibilities provided by the simulation system are: the 
quick construction of models from library elements, 3D 
representation, and the communication of models with actual 
control systems. These simulation models were developed for the 
simulation of various subsystems of a coal mine: underground 
conveyor network subsystems, pumping subsystems and coal face 
subsystems. These simulation models were developed with the 
goal to be used as a quality and reliability assurance tool for new 
process control systems in coal mining. 

Keywords-coal mining; simulation system; visual interactive 
simulation; hardware-in-the-loop   

I. INTRODUCTION  

One of the future developments of simulation is to create 
very detailed simulation models with wide application “from 
the box”, with the minimum involvement of simulationists and 
the maximum involvement of field engineers. Especially in 
underground mining, it is frequently reported that resources 
become less available, and harder to be extracted. The 
technologies of coal mining are well-known. Today mine uses 
mining machinery for mining, transportation, roof support, etc. 
Key topics of interest are the detailed description of machines’ 
functionality, the definition of the exact additional machines 
that may be required, the calculation of the “total cost 
ownership” of machines, the comparison of the use of big 
universal machines to the use of more smaller and specialized 
ones and ultimate product cost definition. These tasks can be 
solved through the use of computer-based simulation of the 
coal mining process. These simulation tasks are known as 
“what-if” ones. The main issue with that particular mining is 
that it is effective in terms of minimum costs and maximum 
productivity only if it is planned correctly. Usually a big 
scheme layout contains various components from different 
vendors interconnected. That makes it hard or, even, 
impossible to predict the exact effectiveness. This situation gets 
worse if there is also a requirement to create new components.  
Due to the importance of these problems, there is a large 

number of papers on the use of simulation in the development 
and optimization of coal mining systems [1-8]. There is also a 
large number of simulation tools, both universal simulation 
systems and specialized systems, and packages for the 
simulation of coal mining systems. While lots of simulation 
tools solve the “what-if” problem, there is significantly less 
such tools that allow building integrated simulation for mines 
hardware development.  

A number of models for various technologies of coal 
mining were developed with the help of a developed simulation 
system. These models are used for the developing of process 
control systems for underground coal mines in Kuznetsk Coal 
Basin (Russia, Western Siberia). The models include both 
“what-if” tasks and development of hardware for control 
systems. 

II. TECHNOLOGIES OF COAL MINING 

There are several well-known technologies of coal mining. 

A. Longwall Mining 

Longwall mining system is a highly-automated, very 
powerful and productive way to mine. It is most-widely applied 
around the world. Its main advantage is that it leaves almost no 
product inside mines. But it is limited with the depth of the 
mine (measured from the surface). Also it is applied in 
relatively flat areas of coal, from 0.8 up to 10 meters high, from 
150 to 450 meters face, and up to 4 kilometers in depth. A 
basic longwall system consists (at least) of an armored face 
conveyor (AFC), a shearer and roof support sections. The AFC 
is connected to an outbound belt conveyor. The shearer cuts the 
product from coal seam face, in a series of passes along the 
AFC. The AFC delivers products to the belt conveyor. The roof 
support moves itself and the AFC, pushing it (and itself) 
forward with hydraulics. One of the problems of longwall 
mining is roof caving. This can lead to serious environmental 
problems. Another problem is that longwall requires significant 
amount of work to be done before its massive equipment is 
installed in production. This work must be planned as well. 
One more problem includes a functioning of specialized 
signaling tools and control systems that monitor marsh gas 
level, dust level and ventilation facilities. If any of the 



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www.etasr.com Okolnishnikov et al.: Simulating the Various Subsystems of a Coal Mine

 

monitored parameters exceed certain save values, the mining 
usually stops. The reason is usually not obvious for personnel 
in mines (gas has no smell, dust does not look dangerous) and 
it can result in turning off the monitoring systems by mine 
personnel in order to increase the mining. Simulation can help 
decide the sufficient levels of ventilation that guarantee safe 
and efficiency. 

B. Highwall Mining 

In case when it is impossible to use longwall, a relatively 
new technology can be applied, named highwall. This is a 
shearer tool, mounted on the top of the chain of special 
sections. These sections can be updated to each other, making a 
long (up to 300 meters) support chain for a shearer. Each 
section can transport the product developed by the shearer to 
the end of a sections chain. The shearer and the chain of 
sections cut the product (coal) from the very thin and curved 
seams. This is the main advantage of the Highwall technology. 

C. Coal Mining of Flat-Laying Coal Seam 

This approach uses a number of front-cutting mining 
machines that cut a coal on a special scheme, and a number of 
self-moving wagons that move a coal from mining machines to 
the storage area. It solves the same problem as highwall 
mining, but requires no specialized equipment. Also this 
approach can be used in deep mining.   

III. THE SIMULATION SYSTEM 

The visual interactive Manufacturing and Transportation 
Simulation System (MTSS) has been developed at the Design 
Technological Institute of Digital Techniques of Siberian 
Branch of the Russian Academy of Sciences (DTIDT) [9, 10]. 
It is a process-oriented discrete simulation system intended to 
aim the development and execution of models of technological 
processes. MTSS is a set of interfaces for creating elementary 
models and for forming complex models. The elementary 
models are ready-to-use submodels of an equipment unit with 
capability of low-level control. A model in MTSS is created by 
graphical connection of images of elementary models. 

The elementary model consists of the following parts:  

 Two-dimensional and three-dimensional graphic images.  

 Input and output parameters. 

 Functionality algorithm describing dependence between 
parameters.                                                                                                                                 

 States which the elementary model can reach during the 
simulation process. 

 Control commands defining switching process between 
elementary models states. 

MTSS is also a tool for simulating complex models. 
Statistics are also available as a short overview when model 
runs, and more statistics are available after model completion. 
This simulation system is effective in providing an easy-to-use 
tool for the rapid creation of simulation models by mining 
engineers. Usually field engineers do not have enough 

expertise in software simulation but they are capable to connect 
correctly elementary models to create the required topology.  

MTSS uses 2D for the graphical editor and 2D and 3D for 
the visualization of the running model. Such approach seems 
more natural for mining engineers, when all installations and 
machines appear first on 2D plans. 3D is more useful for 
visualizing complex vertical movement. Process control 
systems often have two levels: the low level of equipment and 
simple control logic and the upper level of complex control of 
production. Therefore one of the distinguishing features of 
MTSS is a separation of the logic of simulation model into two 
parts: low-level logic and upper level logic. Such separation 
allows us not only to correspond to the usual structure of the 
process control systems but to use such models for embedding 
them into actual process control systems in the following ways: 
to emulate equipment, to simulate upper level logic and to send 
commands to actual process control system for debugging and 
testing. This separation into upper and lower logics also allows 
organizing a switch between various implementations of the 
decomposition. Further, it allows coexisting simulation of 
upper level logic and a proxy that allows communicating with 
the upper level logic of actual process control system. 

The coal mining model can communicate with a new 
process control system developed in DTIDT, to be a source of 
input signals, emulate equipment, test actual control program 
with simultaneous visualization of overall process of mining. 
This allows debugging and tuning of a new process control 
system in accordance with the behavior of the simulated 
system, even simulating various accidents. This allows 
minimizing time and costs on site for commissioning. 

IV. SIMULATION OF UNDERGROUND CONVEYOR NETWORK  

After mining, products are transported by the net of 
conveyors to the enterprise storage. A fragment of the conveyor 
network model is shown in Figure 1.  The conveyor network 
model consists of elementary models of belt conveyors and 
bunkers and requires a simulation model of power supply to 
function. Elementary model of belt conveyor is built with the 
simulation of functionality of its components, such as: structure 
and belt, drive station, control equipment. The developed 
model can provide technological processes, control algorithms 
and the simulation of real information and control signals for 
the process control system. 

The main parameters for elementary model of belt 
conveyor are the following: 

 Position in space. 

 Conveyor maximum load. 

 Drive parameters (amount of motors, capacity, etc.). 

 State (accelerates, work, decelerate, and stop). 

 Set of analog (belt speed, energy consumption, etc.) and 
discrete parameters (inspection of tape returns, cable-role 
switch, etc). This parameters value is defined from EM 
simulation data.  

 Some service parameters and etc. 



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With the help of conveyor network model the following 
problems for the actual process control system were solved: 

 Centralized turning on of conveyors in the direction opposite 
to a coal flow. 

 Turning on of a conveyor after the achievement of required 
speed of a previous conveyor. 

 Turning on of conveyors in defined operating mode. 

 Regulation of the speed of a conveyor belt depending on coal 
size. 

 Emergency turning off of a whole conveyor network by 
turning off of all conveyors simultaneously (halt of the 
conveyor network, for example, if a methane level is high). 

 Optimizing of the energy consumption (lowering of energy 
consumption needed by conveyor network to work). 

 Creation of tools to train the coal mining personnel. 
 

 
Fig. 1.  The fragment of the model of conveyor network. 

V. SIMULATION OF PUMPING SUBSYSTEM  

A fragment of the model of the pumping subsystem is 
shown in Figure 2. This subsystem refers to mine safety 
systems. It averts mine flood. Pumping subsystem model 
consists of pumps, tubes, tanks, water flows and requires 
elements of the electricity subsystem. Pumping simulation is 
based on two parts: fluid distribution and energy consumption 
simulation. The simulation model of this subsystem provides 
technological and underground water pumping out processes 
and energy consumption simulation.  

The main settings are the following: pump efficiency, tube 
throughput, pump energy consumption, tanks capacity, and etc. 
The following problems were solved with the help of the model 
of pumping subsystem: 

 Pumps centralized turning on. 

 Pump turning on in according with selected control mode. 

 Selection of optimized control mode for pumps. 

VI. SIMULATION OF COAL MINING IN VARIOUS TYPES OF 
COAL SEAMS 

A specialized library of simulation models of mining 
machines for coal mining was developed. This library is a part 
of MTSS and its prime goal is to simulate interactively and 
visualize various aspects of coal mining in flat-lying coal seam.  

The library consists of new elementary models of: 

 Highwall mining system. 

 Longwall mining system. 

 Coal seam. 

 Mining machines. 

 Self-moving coal wagon. 

 Storage area. 

The library contains also a simulation model of a flat-lying 
coal seam. This model is a source of the product in a simulation 



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model, while storage area is a consumer of a product. The 
product itself is coal. These new components can communicate 
with existing libraries of MTSS [11-13] which simulate mines 
subsystems like: 

 Belt conveyor subsystem. 

 Power supply subsystem. 

 Ventilation subsystem. 

A simulation model of coal mining subsystem in a flat-
lying coal seam was developed using the library of mining 
machines. Figure 3 contains a sample layout in the simulation 
model of the flat-lying coal seam (2D and 3D view combined 
in different views). The simulation model built from the 
content of the library will simulate the movement of all mobile 
objects of the model. Both 2D (top view) and 3D visualization 
are available. Statistical data are also collected. 

 

 
Fig. 2.  The fragment of the model of pumping subsystem. 

 

 
Fig. 3.  The simulation model of coal mining in flat-lying coal seam         

(4 mining machines and 4 self-moving coal wagons). 

Figure 4 shows a sample layout in another simulation 
model of the flat-lying coal seam. The main window consists of 
6 areas: 

(1) 2D top view. It contains: main mine, side mines. The 
origin coordinates is at the left top corner of this view. 

(2) 3D view. On Figure 4 there is a view from point 3. 

(3) Point of view for the 3D. 

(4) Parameters of a simulation model. 

(5) Specialized view for fast navigation in simulation 
model. 

(6) Settings for the time start, time end and current model 
time. 



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Fig. 4.  The main window of MTSS system while running of simulation model of coal mining in flat-lying coal seam. 

 

The model was created to visualize a new technology of 
coal-mining in flat-lying coal seam. This simulation model also 
allows receiving statistical results for usage of this technology. 
As patent describes, mining is done by frontal winning 
machine, paired with self-moving coal wagons. Patent 
describes the directions of cut of a flat-lying coal seam for the 
frontal winning machine. Simulation model of this process 
allows visualizing the process described. 

For detailed simulation of longwall mining system we 
finished with next decomposition: 

 Armored Face Conveyor (AFC). 

 Shearer. 

 Roof support sections. 

Simulation model for longwall mining system can function 
if it is connected (in terms of MTSS) with the belt conveyor 
simulation model. Also this model requires a power supply 
chain, that means it will require a wire and power transformer 
facility model “connected” to it (in terms of MTSS).  

The goal of creation of simulation of longwall mining 
system is: 

 To create a smart, real-looking mines simulation system. Our 
organization is not in charge for the control systems for 
longwall automation, therefore the primary goal is to provide 
a simulation model that ensures efficient production. 

 To investigate the possible pitfalls and bottlenecks of using 
different longwall configurations for different coal layers. In 
other words, to do simulation research of longwall system 
itself, detached from the rest of the mine simulation system. 

The algorithm for longwall mining system simulation was 
done closer to the control algorithms of the real longwall 
mining system. Today our simulation contains one-way and 
two-way shearing (besides there are more shearing techniques 
combined from these two). 

Figure 5 shows the simplest two-way shearing. In this case, 
shearer will mine the product while it moves in both directions. 
Roof support section will move itself forward (and AFC too) 
each time the shearer passed it. Then it will advance the 
simulation to the time defined, and then simulate the roof 
support sections movement. The amount of mined product will 
be moved to the AFC that will deliver it to the connected belt 
conveyor. Task will repeat these steps until the “done” or 
“postpone” conditions are achieved. 

Task is “done” when shearer reaches the end of an AFC 
line. Task is “postponed” when belt conveyor is overloaded 
and cannot accept the next portion of product or gas level is not 
safe. During any of these steps, the simulation model of flat-
lying coal seam simulates roof fall (behind the roof support) 
and gas level increasing. Also ventilation simulated in a simple 
manner (remove gas from working area, with some defined 
speed). One-way shearing is to shear the product only in one 
direction. After the shearing path is over, the shearer will be 



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returned to its starting position, and only then all roof supports 
advanced to the new position simultaneously. 

 

 
Fig. 5.  The longwall shearer and roof support in two-way shearing. 

In most cases, there is no need to simulate in details any 
technology like longwall or flat-lying coal mining, if it is used 
just as a source of a product for belt conveyor system, for 
example. All that is really needed in such cases are: 

 To define that longwall or flat-lying coal mining is a source 
of a product for a big mining system like conveyor. 

 To determine the performance of the longwall coal mining 
during some time period (working day, 8-hours time interval, 
1-hour time interval). Note that emergency stops (like gas or 
coal dust) are already included in this statistical data. 

The goals of simulation are: 

 To predict how longwall or flat-lying coal seam mining 
automation will behave in details (i.e. movement of its parts 
depending on various situations in mines). 

 To make a detailed visualization of mining process.  

 To define how this mining will impact to the overall 
performance of the mines.  

 To define scenarios of broken or temporarily inaccessible 
parts interactively [14]. 

The achievement of these goals requires a detailed 
decomposition of common longwall (or highwall) mining 
system and a detailed visualization of all its parts. 

Figure 6 shows the hardware installation for the real 
“hardware-in-the-loop” with the combined model and the real 
control hardware for managing one of the belt conveyors 
presented in the model. The other conveyors are managed by 
simulation programs for these belt conveyors simulation 
models. 

VII. CONCLUSION 

Detailed simulation of longwall system, connected with 
detailed simulation of flat-lying coal seam (or multiple flat-
lying coal seams), will allow the creation of  models that will 
not only predict the behavior of big underground mining 
systems, but also the simulation of land subsidence while using 

longwall, especially with very heavy longwall systems that can 
cut 10-meters-high coal seams. The MTSS simulation system 
can be used not only for simulation of existing coal mining 
techniques but also for perspective robotized techniques. The 
library of elements is still growing. It provides the capability to 
create detailed simulation models of underground mining 
facilities, including belt conveyor systems, power supply, 
ventilation, and various coal face models. Such simulation 
models can be used both in solving “what-if” tasks and in 
hardware development for control systems. 

 

 
Fig. 6.  Belt conveyor controlling hardware connected to the simulation 

model of whole mines factory. 

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