In my thesis, I evaluated the rationale behind the investment in a device for compensating reactive power in the boiler room. The system consists of three boilers and five elements for the cogeneration of heat and electricity (CHP), with wood chips used as fuel. The produced energy is used to heat the nearby Dob Penitentiary. CHP units operate throughout the year, but boilers only during the heating season. The electricity consumption profile is both seasonal and base load. Cogenerations produce a total of 225 kW of active power, which is enough for the needs of the boiler room, but since we have many consumers with a need for reactive power, we have to receive that from the grid. In my thesis, I presented solutions for this cost. I started with theory. I described the reactive power, the method of connection and the types of compensation equipment, as well as the formation and effects of higher harmonic components. Based on the data from the network meter, I calculated the excessive absorbed reactive energy and the related annual cost. In order to select suitable compensation equipment, we carried out measurements at the facility. We were interested in the voltage and current conditions, the proportion of active and reactive power and the presence of higher harmonic components. As an alternative possibility of reducing the cost of absorbed reactive energy, I also studied the possibilities of producing reactive power with a synchronous generator and an inverter.