Experimental determination of the kinetics of sorption and gas filtration in coal

[1]Wierzbicki, M., Skoczylas, N., Kudasik, M. (2017). Use of a unipore diffusion model to describe the kinetics of methane release from coal spoil in the longwall environment. Studia Geotechnica et Mechanica39(2), 81-89.WierzbickiM.SkoczylasN.KudasikM.2017Use of a unipore diffusion model to describe the kinetics of methane release from coal spoil in the longwall environmentStudia Geotechnica et Mechanica39281–8910.1515/sgem-2017-0018Search in Google Scholar

[2]Skoczylas, N., Topolnicki, J. (2016). The coal-gas system - the effective diffusion coefficient. International Journal of Oil Gas and Coal Technology12(4), 412-424.SkoczylasN.TopolnickiJ.2016The coal-gas system - the effective diffusion coefficientInternational Journal of Oil Gas and Coal Technology124412–42410.1504/IJOGCT.2016.077300Search in Google Scholar

[3]Sevenster, P.G. (1959). Diffusion of gases through coal. Fuel38 403-418.SevensterP.G.1959Diffusion of gases through coalFuel38403–418Search in Google Scholar

[4]Kudasik, M., Skoczylas, N. (2017). Analyzer for measuring gas contained in the pore space of rocks. Measurement Science and Technology28 10.KudasikM.SkoczylasN.2017Analyzer for measuring gas contained in the pore space of rocksMeasurement Science and Technology281010.1088/1361-6501/aa812dSearch in Google Scholar

[5]Skoczylas, N. (2015). Determining the gas permeability coefficient of a porous medium by means of the bubble-counting flow meter. Measurement Science and Technology26(8).SkoczylasN.2015Determining the gas permeability coefficient of a porous medium by means of the bubble-counting flow meterMeasurement Science and Technology26810.1088/0957-0233/26/8/085004Search in Google Scholar

[6]Młynarczuk, M., Habrat, M., Skoczylas, N. (2016). The application of the automatic search for visually similar geological layers in a borehole in introscopic camera recordings. Measurement85 142-151.MłynarczukM.HabratM.SkoczylasN.2016The application of the automatic search for visually similar geological layers in a borehole in introscopic camera recordingsMeasurement85142–15110.1016/j.measurement.2016.02.043Search in Google Scholar

[7]Wierzbicki, M., Skoczylas, N. (2014). The outburst risk as a function of the methane capacity and firmness of a coal seam. Archives of Mining Sciences59(4), 1023-1031.WierzbickiM.SkoczylasN.2014The outburst risk as a function of the methane capacity and firmness of a coal seamArchives of Mining Sciences5941023–103110.2478/amsc-2014-0070Search in Google Scholar

[8]Dziurzyński, W., Krach, A. (2002). Mathematical model of mine ventilation process interrupted by a rock burst. Archives of Mining Sciences47 333–346.DziurzyńskiW.KrachA.2002Mathematical model of mine ventilation process interrupted by a rock burstArchives of Mining Sciences47333–346Search in Google Scholar

[9]Pajdak, A., Kudasik, M. (2017). Structural and textural characteristics of selected copper-bearing rocks as one of the elements aiding in the assessment of gasogeodynamic hazard. Studia Geotechnica et Mechanica39(2), 51-59.PajdakA.KudasikM.2017Structural and textural characteristics of selected copper-bearing rocks as one of the elements aiding in the assessment of gasogeodynamic hazardStudia Geotechnica et Mechanica39251–5910.1515/sgem-2017-0015Search in Google Scholar

[10]Pajdak, A., Godyn, K., Kudasik, M., Murzyn, T. (2017). The use of selected research methods to describe the pore space of dolomite from copper ore mine, Poland. Environmental Earth Sciences76(11), 389.PajdakA.GodynK.KudasikM.MurzynT.2017The use of selected research methods to describe the pore space of dolomite from copper ore mine, PolandEnvironmental Earth Sciences761138910.1007/s12665-017-6724-4Search in Google Scholar

[11]Wierzbicki, M., Młynarczuk, M. (2013). Structural aspects of gas and dolomite outburst in Rudna copper mine, Poland. International Journal of Rock Mechanics & Mining Sciences57 113-118.WierzbickiM.MłynarczukM.2013Structural aspects of gas and dolomite outburst in Rudna copper mine, PolandInternational Journal of Rock Mechanics & Mining Sciences57113–11810.1016/j.ijrmms.2012.08.007Search in Google Scholar

[12]Kawęcka, J. (1988). Kinetyka sorpcji i dyfuzji. Zeszyty Naukowe AGH. Chemia, 8 115-142.KawęckaJ.1988Kinetyka sorpcji i dyfuzjiZeszyty Naukowe AGH. Chemia8115–142Search in Google Scholar

[13]Éttinger, I.L., Rabczenko, S.A. (1988). Metanoperenos v obrazcachugla i ugolnychplastach. ChimijaTverdogoTopliva4 29-34.ÉttingerI.L.RabczenkoS.A.1988Metanoperenos v obrazcachugla i ugolnychplastachChimijaTverdogoTopliva429–34Search in Google Scholar

[14]Korta, A., red. (1990). Badania energii i szybkości desorpcji na węglach wyrzutowych i niewyrzutowych. IMG PAN (Sprawozdanie z prac w problemie CPBP 03.06. Górotwór jako ośrodek wielofazowy), Kraków.KortaA.red1990Badania energii i szybkości desorpcji na węglach wyrzutowych i niewyrzutowychIMG PAN (Sprawozdanie z prac w problemie CPBP 03.06. Górotwór jako ośrodek wielofazowy)KrakówSearch in Google Scholar

[15]Siricar, S. (1981). On the measurement of sorption kinetics by differential test: effect of the heat of sorption. Carbon19 285-288.SiricarS.1981On the measurement of sorption kinetics by differential test: effect of the heat of sorptionCarbon19285–28810.1016/0008-6223(81)90074-9Search in Google Scholar

[16]Timofiejew, D.P. (1967). Adsorptionskinetik (tłum. z ros). Lipsk: VEB.TimofiejewD.P.1967Adsorptionskinetik (tłum. z ros)LipskVEBSearch in Google Scholar

[17]Skoczylas, N., Kudasik, M., Topolnicki, J. (2018). Model studies on saturation of a coal sorbent with gas taking into account the geometry of spatial grains. Przemysl chemiczny97(2), 272-276.SkoczylasN.KudasikM.TopolnickiJ.2018Model studies on saturation of a coal sorbent with gas taking into account the geometry of spatial grainsPrzemysl chemiczny972272–276Search in Google Scholar

[18]Kudasik, M., Skoczylas, N., Pajdak A. (2017). The repeatability of sorption processes occurring in the coal-methane system during multiple measurement series. Energies10(5), 661.KudasikM.SkoczylasN.PajdakA.2017The repeatability of sorption processes occurring in the coal-methane system during multiple measurement seriesEnergies10566110.3390/en10050661Search in Google Scholar

[19]Gawor, M., Skoczylas, N. (2014). Sorption rate of carbon dioxide on coal. Transport in Porous Media101(2), 269-279.GaworM.SkoczylasN.2014Sorption rate of carbon dioxide on coalTransport in Porous Media1012269–27910.1007/s11242-013-0244-9Search in Google Scholar

[20]Kidder, R. E., La Habra (1957). Unsteady flow of gas through a semi-infinite porous medium. Journal of Applied Mechanics24 329-332.KidderR. E.LaHabra1957Unsteady flow of gas through a semi-infinite porous mediumJournal of Applied Mechanics24329–33210.1115/1.4011542Search in Google Scholar

[21]Gawor, M. (1993). Sorpcja i dyfuzja gazów w węglu kamiennym. Archives of Mining Sciences38 217-261.GaworM.1993Sorpcja i dyfuzja gazów w węglu kamiennymArchives of Mining Sciences38217–261Search in Google Scholar

[22]Gawor, M. (2004). Wyrzuty węgla i gazu w aspekcie badań eksperymentalnych zjawisk gazodynamicznych w brykietach węglowych nasyconych gazem. Prace IMG PAN Rozprawy i Monografie nr 7. Kraków 2004. 163.GaworM.2004Wyrzuty węgla i gazu w aspekcie badań eksperymentalnych zjawisk gazodynamicznych w brykietach węglowych nasyconych gazemPrace IMG PANRozprawy i Monografie nr 7. Kraków2004163Search in Google Scholar

[23]Kudasik, M., Skoczylas, N., Sobczyk, J., Topolnicki, J (2010) Manostat-an accurate gas pressure regulator. Measurement Science and Technology21(8).KudasikM.SkoczylasN.SobczykJ.TopolnickiJ2010Manostat-an accurate gas pressure regulatorMeasurement Science and Technology21810.1088/0957-0233/21/8/085402Search in Google Scholar