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Mikhail A. Semin
Mikhail A. Semin
Researcher, Ph.D.
Mining Institute of the Ural Branch of the Russian Academy of Sciences
Researcher, Ph.D.
Mining Institute of the Ural Branch of the Russian Academy of Sciences
Perm
Russia

Articles

Geotechnical Engineering and Engineering Geology
  • Date submitted
    2021-12-20
  • Date accepted
    2024-05-02
  • Date published
    2024-06-04

A new formula for calculating the required thickness of the frozen wall based on the strength criterion

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A detailed study of the problem of elastoplastic deformation of a frozen wall (FW) with an unlimited height has been carried out. This problem formulation was first introduced and partially studied by Vyalov. The fields of stresses and displacements arising in the FW as a result of the application of external loads are analyzed for several boundary situations - the appearance of a zone of plastic deformations and the propagation of this zone over the entire FW thickness. The latter situation corresponds to the limiting-equilibrium state of the FW, for which Vyalov earlier obtained the formula for the FW thickness. These results served as a starting point for the transition from a one-dimensional problem to a two-dimensional problem of FW stress-strain state with a finite height. Discussions are made about the possibility of constructing a formula for the FW thickness from the condition of the limiting stress state, considering finite height of the unsupported area of the shaft. Numerical simulation of the deformation of the FW is carried out in the FreeFEM ++ package in a two-dimensional axisymmetric formulation within the framework of two calculation schemes with different boundary conditions at the upper end of the FW. Based on the results of the research carried out, a modification of Vyalov's formula is introduced. The modified formula includes a new parameter - the height of the unsupported area of the shaft. For different layers of soils, The conditions, under which the influence of the FW finite height becomes insignificant, are determined.

How to cite: Semin M.А., Levin L.Y. A new formula for calculating the required thickness of the frozen wall based on the strength criterion // Journal of Mining Institute. 2024. p. EDN WEJUBT
Mining
  • Date submitted
    2020-12-16
  • Date accepted
    2021-07-27
  • Date published
    2021-09-29

Features of the thermal regime formation in the downcast shafts in the cold period of the year

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In the cold period of the year, to ensure the required thermal regime in underground mine workings, the air supplied to the mine is heated using air handling systems. In future, the thermodynamic state of the prepared air flow when it is lowered along the mine shaft changes due to the influence of a number of factors. At the same time, the processes of heat and mass exchange between the incoming air and its environment are of particular interest. These processes directly depend on the initial parameters of the heated air, the downcast shaft depth and the presence of water flows into the mine shaft. Based on the obtained experimental data and theoretical studies, the analysis of the influence of various heat and mass transfer factors on the formation of microclimatic parameters of air in the downcast shafts of the Norilsk industrial district mines is carried out. It is shown that in the presence of external water flows from the flooded rocks behind the shaft lining, the microclimatic parameters of the air in the shaft are determined by the heat transfer from the incoming air flow to the underground water flowing down the downcast shaft lining. The research results made it possible to describe and explain the effect of lowering the air temperature entering the underground workings of deep mines

How to cite: Zaitsev A.V., Semin M.A., Parshakov O.S. Features of the thermal regime formation in the downcast shafts in the cold period of the year // Journal of Mining Institute. 2021. Vol. 250. p. 562-568. DOI: 10.31897/PMI.2021.4.9
Mining
  • Date submitted
    2020-05-26
  • Date accepted
    2020-09-23
  • Date published
    2020-12-29

Automated ventilation control in mines. Challenges, state of the art, areas for improvement

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The article is divided into three main parts. The first part provides an overview of the existing literature on theoretical methods for calculating the optimal air distribution in mines according to the criteria of energy efficiency and providing all sections of mines with the required amount of air. It is shown that by the current moment there are many different formulations of the problem of searching the optimal air distribution, many different approaches and methods for optimizing air distribution have been developed. The case of a single (main) fan is most fully investigated, while for many fans a number of issues still remain unresolved. The second part is devoted to the review of existing methods and examples of the automated mine ventilation control systems implementation in Russia and abroad. Two of the most well-known concepts for the development of such systems are automated ventilation control systems (AVCS) in Russia and the CIS countries and Ventilation on demand (VOD) abroad. The main strategies of ventilation management in the framework of the AVCS and VOD concepts are described and also the key differences between them are shown. One of the key differences between AVCS and VOD today is the automatic determination of the operation parameters of fan units and ventilation doors using the optimal control algorithm, which is an integral part of the AVCS. The third part of the article describes the optimal control algorithm developed by the team of the Mining Institute of the Ural Branch of the Russian Academy of Sciences with the participation of the authors of the article. In this algorithm, the search for optimal air distribution is carried out by the system in a fully automated mode in real time using algorithms programmed into the microcontrollers of fans and ventilation doors. Minimization of energy consumption is achieved due to the most efficient selection of the fan speed and the rate of ventilation doors opening and also due to the air distribution shift control and the partial air recirculation systems introduction. It is noted that currently the available literature poorly covers the issue related to emergency operation modes ventilation systems of mines and also with the adaptation of automated control systems to different mining methods. According to the authors, further development of automated ventilation control systems should be carried out, in particular, in these two areas.

How to cite: Semin M.A., Grishin E.L., Levin L.Y., Zaitsev A.V. Automated ventilation control in mines. Challenges, state of the art, areas for improvement // Journal of Mining Institute. 2020. Vol. 246. p. 623-632. DOI: 10.31897/PMI.2020.6.4
Oil and gas
  • Date submitted
    2020-05-26
  • Date accepted
    2020-06-10
  • Date published
    2020-06-30

Theoretical analysis of frozen wall dynamics during transition to ice holding stage

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Series of calculations for the artificial freezing of the rock mass during construction of mineshafts for the conditions of a potash mine in development was carried out. Numerical solution was obtained through the finite element method using ANSYS software package. Numerical dependencies of frozen wall thickness on time in the ice growing stage and ice holding stage are obtained for two layers of the rock mass with different thermophysical properties. External and internal ice wall boundaries were calculated in two ways: by the actual freezing temperature of pore water and by the temperature of –8 °С, at which laboratory measurements of frozen rocks' strength were carried out. Normal operation mode of the freezing station, as well as the emergency mode, associated with the failure of one of the freezing columns, are considered. Dependence of a decrease in frozen wall thickness in the ice holding stage on the duration of the ice growing stage was studied. It was determined that in emergency operation mode of the freezing system, frozen wall thickness by the –8 °C isotherm can decrease by more than 1.5 m. In this case frozen wall thickness by the isotherm of actual freezing of water almost always maintains positive dynamics. It is shown that when analyzing frozen wall thickness using the isotherm of actual freezing of pore water, it is not possible to assess the danger of emergency situations associated with the failure of freezing columns.

How to cite: Semin M.A., Levin L.Y., Bogomyagkov A.V. Theoretical analysis of frozen wall dynamics during transition to ice holding stage // Journal of Mining Institute. 2020. Vol. 243. p. 319. DOI: 10.31897/PMI.2020.3.319
Mining
  • Date submitted
    2019-01-11
  • Date accepted
    2019-03-17
  • Date published
    2019-06-25

Improving Methods of Frozen Wall State Prediction for Mine Shafts under Construction Using Distributed Temperature Measurements in Test Wells

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Development of mineral deposits under complex geological and hydrogeological conditions is often associated with the need to utilize specific approaches to mine shaft construction. The most reliable and universally applicable method of shaft sinking is artificial rock freezing – creation of a frozen wall around the designed mine shaft. Protected by this artificial construction, further mining operations take place. Notably, mining operations are permitted only after a closed-loop frozen section of specified thickness is formed. Beside that, on-line monitoring over the state of frozen rock mass must be organized. The practice of mine construction under complex hydrogeological conditions by means of artificial freezing demonstrates that modern technologies of point-by-point and distributed temperature measurements in test wells do not detect actual frozen wall parameters. Neither do current theoretical models and calculation methods of rock mass thermal behavior under artificial freezing provide an adequate forecast of frozen wall characteristics, if the input data has poor accuracy. The study proposes a monitoring system, which combines test measurements and theoretical calculations of frozen wall parameters. This approach allows to compare experimentally obtained and theoretically calculated rock mass temperatures in test wells and to assess the difference. Basing on this temperature difference, parameters of the mathematical model get adjusted by stating an inverse Stefan problem, its regularization and subsequent numerical solution.

How to cite: Levin L.Y., Semin M.A., Parshakov O.S. Improving Methods of Frozen Wall State Prediction for Mine Shafts under Construction Using Distributed Temperature Measurements in Test Wells // Journal of Mining Institute. 2019. Vol. 237. p. 268. DOI: 10.31897/PMI.2019.3.274