The thesis begins by discussing renewable energy sources, detailing the advantages and disadvantages of solar energy, wind, water, biomass, and biogas. It then explains the influence of distributed sources on the stability of the power system, with a focus on inertia and the importance of rotary machines and motors for maintaining stability. Subsequently, examples of connecting renewable energy power plants to the grid are provided, with the advantages and disadvantages of each type of connection discussed individually. The paper then moves on to describe system frequency stability, particularly the balance between production and consumption, and explains voltage stability, illustrated with PV and QV curves. Following this, the impact of distributed generation on power system protection is examined, especially with regard to changes in short-circuit current values and their effect on protection settings. The types of protection used for distributed renewable energy sources are also explained. The final section of the thesis describes the parameters and scheme of the IEEE 9 Bus system network, which is simulated using the DigSILENT software package. The simulation consists of seven cases: in the first case, the power flow of the system under normal operation is simulated; in the second case, a short circuit on one of the lines is modeled. The third case demonstrates the system's unstable state, while the fourth, fifth, sixth, and seventh cases analyze the transient stability of the system in relation to the level of wind turbine penetration, specifically the replacement of conventional generation from synchronous generators with wind turbines. In the seventh chapter, the parameterization of the protection of renewable energy sources connected via the inverter interface is analyzed, and a proposal is provided. The differences in the parameterization of conventional sources versus renewable energy sources connected via the inverter interface are also discussed. The method of using overcurrent, over/undervoltage, and over/underfrequency protection is described, along with how the lack of inertia in the inverter affects the settings and parameterization of protection and protective devices.