Ordinary Portland cement presents favourable physico-mechanical properties with use of local raw materials and low production costs. Nevertheless, cement industry consumes a lot of energy and the clinkerization process causes high CO2 emissions. Therefore, there is a burgeoning interest in the development and characterization of cement, which could reduce the energy used in production of cement clinker and the associated greenhouse gas emissions. One method of reducing the environmental impact is the use of the alternative binders such as belite-sulfoaluminate clinkers (BCSA), the main phases of which are belite, ye'elimite, ferrite and anhydrite. The aim of the master's thesis was to investigate to what extent the primary raw materials can be replaced by the secondary ones, and how these and process parameter (temperature) affect the properties of belite-sulfoaluminate clinkers. For the research, clinkers of three different assemblies with different range of main phases and four different series with different input materials were prepared. As the secondary raw material, bottom ash and red mud were used. Homogenized raw materials were burned at 1150 °C, 1200 °C and 1250 °C. The phase composition of clinkers was determined by X-ray powder diffraction analysis and quantitatively by Rietveld's analysis, while microstructure and the integration of foreign ions into the main phases of clinkers by Scanning Electron Microscopy with Energy Dispersive Spectroscopy. The analyses confirmed that during the clinkerization in addition to the predicted main phases of clinkers (belite, ye'elimite, ferrite and anhydrite), some of the minor phases (ternesite, periclase, perovskite, calcium aluminate and free lime) were formed. Results showed that with increasing temperature the amount of ye'elimite and ferrite does not change significantly, while the amount of belite and anhydrite increases. Their formation is strongly influenced by the phase ternesite, which decreases the amount with increasing temperature. The microstructure is similar in the analytically pure raw material series, while it changes in clinkers from natural raw materials and with the addition of secondary raw materials, resulting from incorporation of foreign ions (NaO, K2O, MgO).