Course description
Hydroelectric power plants
Basics of hydrodynamics, water flow in pipes and channels, basics of turbo machines, design and operating characteristics of turbines, turbine control, dams and barriers, hydraulic hydroelectric schemes, types of hydroelectric power plants regarding accumulation, water heights and flow, and mode of operation.
Thermal power stations
Basics of thermodynamics, combustion processes and steam boilers, process efficiency, characteristics of steam and gas turbines, problems of emissions and impact to the environment, systems to reduce emissions of thermal power plants.
Nuclear power plants
Fundamentals of nuclear reactions, relation between mass and energy, characteristics of the most common types of nuclear reactors, operation of reactors, nuclear power plant systems, natural radiation and radiation protection, radioactive waste, their effects to the environment and disposal, nuclear power plants safety, risk assessment methods.
Course is carried out on study programme
2nd Cycle Postgraduate Study Programme in Electrical Engineering
Objectives and competences
Student will learn basic mechanisms of primary energy conversion to electric energy with classic technologies. Student will be capable to assess energy potentials regarding their conversion technologies into electric energy. Student will learn structure and functions of components and their interactions within conventional power plants. The problems and possible solutions regarding the spatial planning related with electric power systems will be communicated. Student will learn theoretical mathematical models of the processes of converting the energy in power plants and the related simplifications of complex expressions where appropriate.
Learning and teaching methods
Lectures and exercises. Part of the pedagogical process will be carried out with the help of ICT technologies and the opportunities they offer.
Intended learning outcomes
Student will be capable to:
– calculate conversion of primary energy into electric energy in classical power plants,
– derive the basic equations, which represent the physical processes in power plants,
– sketch the plant operation processes and their main components,
– assess efficiency of processes related to energy conversion,
– interpret the operating parameters of classical sources of energy,
– solve the complex technical problems in the field of conversion to electric power in hydroelectric power plants, thermal power plants and nuclear power plants.
Reference nosilca
- BRICMAN REJC, Živa, ČEPIN, Marko. Izboljšana metoda za oceno zanesljivosti proizvodnje v elektroenergetskem sistemu. Elektrotehniški vestnik, 2013, letn. 80, št. 1/2, str. 57-63.
- ČEPIN, Marko, VOLKANOVSKI, Andrija. Nova faktorja pomembnosti v elektroenergetskih sistemih. Elektrotehniški vestnik, 2009, letn. 76, št. 4, str. 177-181.
- BRICMAN REJC, Živa, ČEPIN, Marko. Estimating the additional operating reserve in power systems with installed renewable energy sources. International journal of electrical power & energy systems, Nov. 2014, vol. 62, str. 654-664.
- GJORGIEV, Blaže, ČEPIN, Marko, VOLKANOVSKI, Andrija, KANČEV, Duško. Generation scheduling analyses of the Slovenian power system in future. Elektrotehniški vestnik, 2014, letn. 81, št. 1/2, str. 20-26.
- 5. KANČEV, Duško, GJORGIEV, Blaže, VOLKANOVSKI, Andrija, ČEPIN, Marko. Time-dependent unavailability of equipment in an ageing NPP : sensitivity study of a developed model. Reliability engineering & systems safety, 2016, vol. 148, str. 11-20.
Study materials
- B. Orel: Energetski pretvorniki I, Založba FER, Ljubljana 1992
- B. Orel: Energetski pretvorniki II, Založba FER, Ljubljana 1993
- R. K. Rajput, Power Plant Engineering, Laxmi Publications, Fourth edition, 2008
- G. Kessler, Sustainable and Safe Nuclear Fission Energy, Springer 2012