References
- Sidor J., (1997) Development of vibratory crushers design, Maszyny Górnicze, vol. 77, pp. 30-37.
- Sidor J., Mazur M., (2017) Application of vibration technology in crushing processes. Ceramic Materials, vol. 69 nr 1, pp. 52-56.
- Machines for very fine crushing (1993) Materials of Mekhanobr-Technogen, Sankt Petersburg.
- Halicka A., Ogrodnik P., Zegardło B., (2013) Using ceramic sanitary ware waste as concrete aggregate, Construction and Building Materials, vol. 48, pp. 295-305.
- Sidor J., Mazur M., (2015) Comparative studies of vibratory crushing process performed in jaw crusher, Ceramic Materials, vol. 67 nr 1, pp. 62-66.
- Sidor J., Mazur M., (2015) Application of vibration technology in crushing processes, Transport Przemysłowy i Maszyny Robocze, vol. 3, pp. 60-65.
- Sidor J., Mazur M., (2014) Examination of crushing rock crystal in a vibratory jaw crusher, Ceramic Materials, vol. 66 nr 1, pp. 32-36.
- Sidor J., Feliks J., Mazur M., (2013) Crushers for coal disintegration in conditions of underground mines, Transport Przemysłowy i Maszyny Robocze, vol. 3, pp. 71-74.
- Feliks J., Mazur M., (2022) Application of impact hammer crusher for rock salt purification. Postępy Techniki Przetwórstwa Spożywczego, vol. 32/61 nr 2, pp. 11-18.
- Mazur M., Feliks J., (2023) The use of vibratory jaw crusher for feed preparing for granulation proces, Konferencja naukowo-techniczna: przemysł przyjazny dla środowiska: 27-29 marca 2023 Gliwice, Instytut Techniki Górniczej KOMAG, pp. 43-50.
- Mazur M., (2010) Examination of quartzite and diabase vibratory crushing, Materials of Polish Conference of Young Scientists, Kraków, vol. 5, pp. 93-101.
- Mazur M., (2017) Research of crushing efficiency in vibra-tory jaw crushers, Doctoral thesis, AGH University of Science and Technology, Unpublished.
- Mazur M., (2019) Determination of Crushing Energy During Vibratory Crushing, New Trends in Production Engineering, vol. 2, pp. 287-294.
- Mazur M., (2017) Method of determining the Bond Work Index in vibratory crushing, SGEM2017 Conference Proceedings, vol. 17, issue 11, pp. 903-910.
- Zawada J., (1995) Obciążenia graniczne i pękanie skał, Wydawnictwo Naukowe PWN.
- Ballantyne G.R., Powell M.S., (2014) Benchmarking comminution energy consumption for the processing of copper and gold ores, Minerals Engineering, vol. 65, pp. 109-114.
- Galos K., Szlugaj J., Burkowicz A., (2016) Sources of limestone sorbents for flue gas desulphurization in Poland in the context of the needs of domestic power industry, Polityka energetyczna – energy policy journal, Vol. 19, No. 2.
- Szlugaj J., Naworyta W., (2015) Analiza zmian podaży gipsu w Polsce w świetle rozwoju odsiarczania spalin w elektrowniach konwencjonalnych, Gospodarka Surowcami Mineralnymi – Mineral Resources Management, vol. 31, z. 2.
- Roszczynialski W., Gawlicki M., (1997) Kierunki zagospodarowania produktów odsiarczania spalin. Materiały VII Konferencji „Aktualia i perspektywy gospodarki surowcami mineralnymi”. Polanica Zdrój.
- Galos K., Smakowski T., Szlugaj J., (2003) Flue-gas desulphurisation products from Polish coal-fired power plants. Applied Energy, vol. 75, pp. 257-265.
- Medina C., Sánchez de Rojas M.I., Frías M., (2012) Reuse of sanitary ceramic wastes as coarse aggregate in eco-efficient concretes, Cement & Concrete Composites, vol. 34, pp. 48-54.
- Silva J., de Brito J., Veiga R., (2008) Fine ceramics replacing cement in mortars partial replacement of cement with fine ceramics in rendering mortars, Mater Struct, vol. 41, pp. 1333-1344.
- Puertas F., García I., Barba A., Gazulla M.F., Palacios M., Gómez M.P., (2008) Ceramic wastes as alternative raw materials for Portland cement Clinker production, Cem Concr Compos, vol. 30, pp. 798-805.
- Guerra I., Vivar I., Liamas B., Juan A., Moran J., (2009) Eco-efficient concretes: The efffect of using recycled ceramic material from sanitary installations on the mechanical properties of concrete, Waste Management vol. 29, pp. 643-646.
- Halicka A., Zegardło B., (2011) Odpady ceramiki sanitarnej jako kruszywo do betonu. Przegląd budowlany, vol. 7-8, pp. 50-55.
- Najm H.M., Ahmad S., (2022) The use of waste ceramic optimal concrete for a cleaner and sustainable environment – a case study of mechanical properties, Civil and environmental engineering reports, vol. 32, pp. 85-115.
- Sidor J., (2006) The investigations of the very fine crushing of sanitary ceramic production waste in the vibratory crusher, Zagadnienia urządzeń ochrony środowiska. Monografie Akademia Górniczo-Hutnicza im. Stanisława Staszica w Krakowie. Wydział Inżynierii Mechanicznej i Robotyki, vol. 32, pp. 277-286.
- Sidor J., Mazur M., Feliks J., (2016) Examination of mineral and ceramic materials vibratory crushing, Mechanizacja, automatyzacja i robotyzacja w górnictwie: Monografia: praca zbiorowa, vol. 2, p. 134-141.
- Sidor J: (2008) Preliminary investigations of industrial line of mechanical processing of ceramic wastes for recycling, Polish Journal of Environmental Studies, vol. 17 no. 3A, pp. 507-510.
- Zarogastkij L.P., Azbel J.I. (1993) Universal technique of crushing and separation of primary and secondary raw materials. Russian-Polish Scientific and Technical Seminar on: “Modern technologies of crushing mineral raw materials.” Lublin.