References
- 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.
- Skoczylas, N., Topolnicki, J. (2016). The coal-gas system - the effective diffusion coefficient. International Journal of Oil Gas and Coal Technology12(4), 412-424.
- Sevenster, P.G. (1959). Diffusion of gases through coal. Fuel38 403-418.
- Kudasik, M., Skoczylas, N. (2017). Analyzer for measuring gas contained in the pore space of rocks. Measurement Science and Technology28 10.
- 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).
- 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.
- 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.
- Dziurzyński, W., Krach, A. (2002). Mathematical model of mine ventilation process interrupted by a rock burst. Archives of Mining Sciences47 333–346.
- 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.
- 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.
- 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.
- Kawęcka, J. (1988). Kinetyka sorpcji i dyfuzji. Zeszyty Naukowe AGH. Chemia, 8 115-142.
- Éttinger, I.L., Rabczenko, S.A. (1988). Metanoperenos v obrazcachugla i ugolnychplastach. ChimijaTverdogoTopliva4 29-34.
- 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.
- Siricar, S. (1981). On the measurement of sorption kinetics by differential test: effect of the heat of sorption. Carbon19 285-288.
- Timofiejew, D.P. (1967). Adsorptionskinetik (tłum. z ros). Lipsk: VEB.
- 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.
- 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.
- Gawor, M., Skoczylas, N. (2014). Sorption rate of carbon dioxide on coal. Transport in Porous Media101(2), 269-279.
- Kidder, R. E., La Habra (1957). Unsteady flow of gas through a semi-infinite porous medium. Journal of Applied Mechanics24 329-332.
- Gawor, M. (1993). Sorpcja i dyfuzja gazów w węglu kamiennym. Archives of Mining Sciences38 217-261.
- 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.
- Kudasik, M., Skoczylas, N., Sobczyk, J., Topolnicki, J (2010) Manostat-an accurate gas pressure regulator. Measurement Science and Technology21(8).