Numerical simulation of the influence of stationary louver and coal particle size on distribution of pulverized coal to the feed ducts of a power plant burner

Živković, Goran; Nemoda, Stevan; Stefanović, P; Radovanović, Predrag

doi:10.2298/tsci0904079z

Cited by 6 publications

(5 citation statements)

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“…The calculation of heat losses comprises the following elements: natural convection outside the mill and ducts, radiated losses from the external surfaces and the internal convection of the preheated air and the pulverized coal mixture. The experimental and numerical studies of the multiphase flow and temperature distribution in the VM, presented in , illustrate this aspect of the coal mill characterization. The heat balance calculation for the Kostolac B thermal power plant coal mills shows that the heat emitted from the mill body to the environment is about 1200 kW, which is 4% losses of the total amount of heat contributed by hot primary air entering the mill and the heat generated by grinding.…”

Section: Ventilation Millmentioning

confidence: 83%

“…The technical characteristics of the VM are described in .The multiphase flow (air mixture) in the VM consists of recirculated gases, coal powder and abrasive particles. The milling quality, the coal powder distribution, and the ventilation characteristic of the mill depend on the mill design as pointed out in . The pulverization of coal into fine particles is carried out in order to increase the specific surface area and to optimize the rate of heat and mass transfer between coal particles and the surroundings hot gas.…”

Section: Ventilation Millmentioning

confidence: 99%

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Numerical and experimental study of temperature distribution on thermal plant coal mill walls

Kozić

Ristić²,

Katavić³

et al. 2017

Env Prog and Sustain Energy

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This article presents results of a numerical and experimental study of the temperature distribution inside and on the walls of the ventilation mill in the Kostolac B power plant, Serbia. This is very important because heat exchange between gas mixtures, ventilation mill walls and the environment, influences coal powder temperature, the combustion process, and the emission of greenhouse gases. The most complex multi-phase model in the Euler-Euler approach has been used through the ANSYS FLUENT code, for the numerical simulation of temperature distribution. Two ventilation mill models have been considered, one with zero wall thickness and the other one with steel walls, with and without insulation. An infrared thermographic camera was used for monitoring the temperature distribution on the outside wall of the ventilation mill housing, before insulator reparation, while after the reparation measurements were carried out at the selected points with infrared thermometer. The experimental results were used for verifying the results of the numerical simulation method as well as for detecting the damaged insulation.

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Section: Ventilation Millmentioning

confidence: 83%

Section: Ventilation Millmentioning

confidence: 99%

Numerical and experimental study of temperature distribution on thermal plant coal mill walls

Kozić

Ristić²,

Katavić³

et al. 2017

Env Prog and Sustain Energy

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“…It is especially useful when investigations on complex thermal power plants are needed [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. There is a wide range of software for numerical simulations.…”

Section: Methodsmentioning

confidence: 99%

Numerical simulation of multiphase flow in ventilation mill and channel with louvers and centrifugal separator

Kozić¹,

Ristić²,

Puharić³

et al. 2011

THERM SCI

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This paper presents the results of numerical flow simulation in ventilation mill of Kostolac B power plant, where louvers and centrifugal separator with adjustable blade angle are used. Numerical simulations of multiphase flow were performed using the Euler-Euler and Euler-Lagrange approach of ANSYS FLUENT software package. The results of numerical simulations are compared with measurements in the mill for both types of separators. Due to very complex geometry and large number of the grid cells, convergent solution with the Eulerian model could not be obtained. For this reason the mixture model was employed resulting in very good agreement with measurements, concerning the gas mixture distribution and velocity at the main and secondary burners. There was large difference between the numerical results and measurements for the pulverized coal distribution at the burners. Taking into consideration that we analyzed dilute mixture with very low volume fraction of the coal, the only choice was the Euler-Lagrange approach, i.e. discrete phase model limited to volume fraction of the discrete phase less than 10-12%. Obtained distributions of the coal at the burners agree well for both types of separators

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“…This unit built in 1979, with nominal steam capacity 920 t/h and gross power 308 MWe, at the end of 2006 had more than 150000 hours on electric network, with 750 stop/starts and generated 235 GWh. In period 2006 to 2011 applied research including measurements and analysis, calculation and numerical simulation of mills/boiler process parameters made a basis for investment decision and step by step realization [25][26][27][28][29][30][31][32]. Improved mills capacity (up to 110 t/h), coal dust concentration distribution over main/vapour burner, and tightness of mills/air tract and boiler, enabled improved combustion process, higher heat generation in the whole furnace with originally projected flue gas temperature at the furnace exit and lower NO x emission (from 440-510 mg/Nm 3 before to <330 mg/Nm 3 after rehabilitation and modernization).…”

Section: Applied Research Dealing Problems Of Pc Boiler Life Cycle Exmentioning

confidence: 99%

Review of the investigations of pulverized coal combustion processes in large power plants in laboratory for thermal engineering and energy: Part B

et al. 2019

Self Cite

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Paper presents short review of research problems, applied methods for solving problems and main results obtained by the researchers in Laboratory for Thermal Engineering and Energy (LTE) of the "Vinča" Institute of Nuclear Sciences, Belgrade, Serbia dealing with pulverized coal combustion processes and technologies for reduction of pollutions problems at thermal power plants in a period since 2000. The presented results were published in numerous studies realized for different users, Ph. D., Masters, and Specialist thesis, in international and domestic scientific journals and monographs, presented at numerous international and domestic scientific conferences, etc. Presented research projects and results of applied research projects realized at pulverized coal combustion thermal power plants clearly show that LTE team was involved in key activities of rehabilitation and modernization, including implementation of best available technologies for pollution reduction at thermal power plants, in the region of South East Europe.

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Numerical simulation of the influence of stationary louver and coal particle size on distribution of pulverized coal to the feed ducts of a power plant burner

Cited by 6 publications

References 0 publications

Numerical and experimental study of temperature distribution on thermal plant coal mill walls

Numerical and experimental study of temperature distribution on thermal plant coal mill walls

Numerical simulation of multiphase flow in ventilation mill and channel with louvers and centrifugal separator

Review of the investigations of pulverized coal combustion processes in large power plants in laboratory for thermal engineering and energy: Part B

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