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Any industrial process needs to work with the optimal operating conditions and thus the evaluation of their robustness is a critical issue. A modeling of a laboratoryscale wire-to-plane two stages electrostatic precipitator for guiding the identification of the set point, is presented this in paper. The procedure consists of formulating recommendations regarding the choice of optimal values for electrostatic precipitation. A twostages laboratory precipitator was used to carry out the experiments, with samples of wood particles of average granulometric size 10 μm. The parameters considered in the present study are the negative applied high voltage of the ionization stage, the positive voltage of the collection stage and the air speed. First, three “one-factor-at-a-time” experiments were performed followed by a factorial composite design experiments, based on a two-step strategy: 1) identify the domain of variation of the variables; 2) set point identification and optimization of the process.
Czasopismo
Rocznik
Tom
Strony
609--619
Opis fizyczny
Bibliogr. 25 poz., rys., wykr., wz.
Twórcy
autor
- APELEC Laboratory, Djillali Liabes University Sidi Bel-Abbes, Algeria
autor
- APELEC Laboratory, Djillali Liabes University Sidi Bel-Abbes, Algeria
autor
- APELEC Laboratory, Djillali Liabes University Sidi Bel-Abbes, Algeria
autor
- APELEC Laboratory, Djillali Liabes University Sidi Bel-Abbes, Algeria
Bibliografia
- [1] Jedrusik M., Swierczok A., Teisseyre R., Experimental study of fly ash precipitation in a model electrostatic precipitator with discharge electrodes of different design. Powder Technology: 295301 (2003).
- [2] Hoenig, S.A., New application of electrostatic technology to control of dust, fumes, smokes and aerosols. IEEE Transactions on Industry Applications IAS-17(4): 386-391 (1981).
- [3] White HJ., Industrial Electrostatic Precipitation, Reading, MA. Wesley G.O. (1963).
- [4] Onda K., Kasuga Y., Kato K. et al., Electric discharge removal of SO2and NO2 from combustion flue gas by pulsed corona discharge. Energy Conversion and Management 38: 1377-1387 (1997).
- [5] Balcerak M., Hołub M., Pałka R., High voltage pulse generation using magnetic pulse compression. Archives of Electrical Engineering 62(3): 463-472 (2013).
- [6] Hołub M., Study on the influence of output inductance on DBD plasma uniformity. Archives of Electrical Engineering 63(2): 263-272 (2014).
- [7] Balcerak M., Hołub M., Pałka R., High voltage pulse generation using magnetic pulse compression. Archives of Electrical Engineering 62(3): 463-472 (2013).
- [8] Masłowski G., Corona current concept in lightning return-stroke models of engineering type. Archives of Electrical Engineering 59(3-4): 177-188 (2010).
- [9] Artino A., Cârdu M., Electrostatic precipitators used in the ecological conversion of power in coal-fired thermoelectric power plants. Energy Convers Manage 35: 477-81 (1994).
- [10] Macarie R., Martin D., New technologies for the electrostatic precipitators pulsed energization in energetic. Energy Convers Manage 38: 511-6 (1997).
- [11] Miloua, F., Gouri, R., Tilmatine, A. et al., Optimization of the rapping pro-cess of an intermittent electrostatic precipitator. European Physical Journal of Applied Physics, EDP Sciences 41(1): 81-85 (2008).
- [12] Remaoun SM., Tilmatine A., Miloua F. et al., Optimization of a Cost-Effective“Wire-Plate”Type ESP for Installation in a Medical Wastes Incinerator. IEEE/IAS Joint. Conference on Electrostatics, Waterloo, Canada, pp. 12-15 (2012).
- [13] Adamiak K., Numerical models in simulating wire-plate electrostatic precipitators: a review. J. Electrostatics 71: 673-80 (2013).
- [14] Khalid U., Eldein A., Experimental study of V-Icharacteristics of wire-plate electrostatic precipitators under clean air conditions. J. Electrostatics 71: 228-34 (2013).
- [15] Gajewski J.B., Accuracy of cross correlation velocity measurements in two-phase gasesolidflows. Flow Meas. Instrum 30: 133-137 (2013).
- [16] Juliusz B., Gajewski., Monitoring of electrostaticfire and explosion hazards at the inlet to electrostatic precipitators. Journal of Electrostatics 72: 192-197 (2014).
- [17] Al-Hamouz Z., Numerical and experimental evaluation of fly ash collection efficiency in electrostatic precipitators. Energy Conversion and Management 79: 487-497 (2014).
- [18] Miloudi M., Medles K., Tilmatine A. et al., Modeling and optimization of a propeller-type tribocharger for granular materials. Journal of Electrostatics 69(6): 631-637 (2011).
- [19] Rezouga M., Tilmatine A., Ouiddir R., Medles K, Experimental Modelling of the Breakdown Voltage of Air Using Design of Experiments Advances in electrical and computer engineering. Acadamy of Technical Science of Romania 9(1): 41-45 (2009).
- [20] Medles K., Tilmatine A., Rezouga M. et al., Experimental Designs Methodology And Its Application to an Electrostatic Separation Process. Materials Technology: Advanced Performance Materials 21(3): 144-147(4) (2006).
- [21] Medles K., Dascalescu L., Tilmatine A. et al., Experimental Modeling of the Electrostatic Separation of Granular Materials. Particulate Science and Technology, http://www.informaworld.com/ smpp/title~content=t713774907~db=all~tab=issueslist~branches=25 - v2525 (2): 163-171, (2007).
- [22] Frigon N.L., Mathews D., Practical Guide to Experimental Design. 1st ed., Wiley, New York (1996).
- [23] Taguchi G., System of Experimental Designs. Kraus International Publications, New York (1987).
- [24] Eriksson L., Johansson E., Kettaneh-Wold N. et al., Design of Experiments, Principles and Applications. Learnways AB, Stockholm (2000).
- [25] MODDE 5.0, User guide and tutorial. Umetrics (1999).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-20fed301-3f64-48e2-af1d-ca2419eb44eb