In the introductory part of the project, the reasons for the development of combined cogeneration cycle and its operating principle were presented. Furthermore, the main components of the gas turbine and steam turbine were described, along with the basic methods for increasing the efficiency of the basic gas and steam cycles, accompanied by diagrams and charts. The selected gas turbine was the Siemens SGT-800, and the selected steam turbine was the Siemens SST-600, with a 2x1 configuration. Two SGT-800 turbines produce 125 MWe, while one Siemens SST-600 produces the remaining 75 MWe, with the capability of producing more if necessary. In addition to the 200 MWe of electrical power, it was also necessary to extract process steam at 8 bar, 300 °C, and a mass flow rate of 30 t/h. After selecting the turbines, all the states of the gas and steam cycles needed to be determined in order to calculate specific work and heat rates, and ultimately the efficiency level. For the ambient temperature, a standard air temperature of 15 °C and a pressure of 1 bar were chosen. The gas turbine combustion chamber utilized natural gas with a lower heating value of 35516 kJ/kg, and by burning it with a mass flow rate of 271 kg/s, flue gases with a temperature of 1505 °C were obtained. Due to these exceptionally high temperatures, the turbine materials would have to be highly refractory, and the blades would need some cooling method. The flue gases are cooled to a temperature of 596 °C by expansion through the turbine and are further utilized in the process, specifically in the heat recovery steam generator (HRSG). In the HRSG, heat exchange occurs between the feedwater/steam of the steam process, producing 134.792 kg/s of superheated steam at a temperature of 420 °C and a pressure of 18.5 bar through additional burning. The flue gases are further cooled in the HRSG and exit through the chimney into the environment at a temperature of 180 °C. The expanded superheated steam is condensed in the water condenser at a pressure of 1 bar, and the condensate pump draws the condensate into the deaerator at a pressure of 7 bar, where the water undergoes further processing. From there, the feedwater is sent to the HRSG for the repetition of the cycle using a feedwater pump. All known basic losses were taken into account in the calculation, resulting in an overall efficiency of the combined process of 40.98%, which is realistic for the basic combined process. To further improve its efficiency, methods such as reheating, steam intercooling, and feedwater regeneration should be employed. However, all improvements lead to increased complexity and investment costs, so decisions should be carefully analyzed from both economic and engineering perspectives