Introduction to Electricity Industry PhDr. Tomáš Vlček, Ph.D. International Relations and Energy Security Department of International Relations and European Studies Content  Basic Quantities and Units  Energy Transformation  Basics of Electricity  Electricity System  AC/DC - History and Differences  Transfer and Distribution of Electricity  Pricing and Market  Regulation of Electricity  Electricity Trading What is Electricity? http://www.youtube.com/watch?v=8gvJzrjwjds What is Electricity? Electricity has many advantages  easy to handle  simple transfer  it is clean and non-polluting  it is elegant and inexpensive Basic Quantities and Units  Voltage U (V) unit 1 volt  Current I unit 1 ampere  Resistance R unit 1 ohm (Ω)  Installed capacity P unit 1 watt  Energy / work E unit 1 joul (Ws), j Wh  Frequency f unit 1 hertz  Efectivity η dimensionless quantity (%) Basic Quantities and Units  fluorescent lamp 8–25 W  lightbulb 25–200 W  laptop (sleep) 12 W  laptop 20 W  PC + LCD monitor 80 W  colour TV 100 W  washing machine 500-2,000 W  iron 1,000 W  el. pan/hot-plate 1,200 W  toaster 1,200 W  dishwasher 1,500 W  vacuum-cleaner 1,000–2,000 W*  tea-kettle 1,200–2,000 W  electric locomotive 2 MW  electric induction furnace 40 MW * 9/2014 1,600+ W banned in EU; 1/2017 900+ W banned in EU Basics of Electricity  Installed Capacity  Electricity Production (work)  Capacity Factor  Efficiency and Energy Transformation Installed Capacity in the Electricity Grid on 31 December 2012 Type of Power Station Installed Capacity (MWe) Percentage (%) Thermal Power Station 10644 51.9 Gas Combined Cycle Power Station 521 2.5 Gas Fired Power Station 750 3.7 Hydroelectricity 1069 5.2 Pumped-storageHydroelectricity 1147 5.6 Nuclear Power Station 4040 19.7 Wind Power 263 1.3 Solar Power 2086 10.2 Geothermal Power 0 0 Total 20520 100 Source: Energetický regulační úřad, 2013, s. 11. Gross Electricity Production in 2012 Type of Power Station Electricity Production (GWh) Percentage (%) Thermal Power Station 47 261.0 53.9 Gas-fired and Gas Combined Cycle Power Station 4 435.1 5.1 Nuclear Power Station 30 324.2 34.6 Hydroelectricity (incl. Pumpedstorage Hydroelectricity) 2 963.0 3.4 Wind Power 417.3 0.5 Solar Power 2 173.1 2.5 Total brutto production 87 573.7 100 Total netto production 81 088.4 92.6% of brutto production Source: Energetický regulační úřad, 2013; percentages by T. Vlček. Capacity Factor in 2012 Type of Power Station Potential Eletricity Production (GWh) Electricity Production (GWh) Capacity Factor (%) Thermal Power Station 93 241.4 47 261.0 50.7 Gas-fired and Gas Combined Cycle Power Station 11 133.9 4 435.1 39.8 Nuclear Power Station 35 390.4 30 324.2 85.7 Hydroelectricity (incl. Pumped-storage Hydroelectricity) 19 412.2 2 963.0 15.3 Wind Power 2 303.9 417.3 18.1 Solar Power 18 273.4 2 173.1 11.9 Source: Energetický regulační úřad, 2013; percentages by T. Vlček. How did I calculate the Potential Electricity Production? Boiler variants of Coal-fired power plants Type Pressure (MPa) Temperature (° C) Efficiency (%) Sub-critical 12 – 20 510 – 560 35 on average Critical 23 – 25 510 – 560 35 – 47 Super-critical 25 – 36 580 – 600 up to 47 Ultra-super-critical 25 – 36 600 – 700 up to 54 Source: Kolat, Roubíček, & Kozaczka, 2008, s. 20. Technical aspects of electricity production in different power stations Type of Power Station Capacity factor (%) Conversion efficiency (%) Thermal 50 – 80 32 – 47 Nuclear 80 – 95 27 – 33 Gas Combined Cycle Power Station 11 – 60 38 – 60 Solar 5 – 20 12 – 14 (25, 34) Wind Turbines 15 – 28 20 – 45 Pumped-storage Water 10 – 15 85 – 95 Water-flow 45 – 70 85 – 95 Source: author Energy Transformation and Efficiency Energy Transformation and Efficiency LIGNITE, HARD COAL, NATURAL GAS, OIL, BIOMASS ENERGY SOURCE CHEMICAL ENERGY STEAM THERMAL ENERGY ROTATION KINETIC ENERGY ELECTRICITY PRODUCT DEVICE: Boiler (combustion) Turbine Generator / Alternator LOSSES: <10-15 % 50 % <5 % EFFICIENCY is the sum of effectivity of all energy transformation processes, in the picture above it is calculated as 100 x 0.85 x 0.5 x 0.95 = 40.375% ELECTRICITY is an intermediate form of energy, we do not use electricity, but heat, light, mechanical energy = effectivity (losses) of downstream appliances is also in play How much will I pay for 2 litres of tea, if I have a 1 l electric teapot (P = 1,500 We)? It takes 5 minutes to boil the water in the teapot and the electricity costs 4 CZK /1 kWh. How much will I pay for 2 litres of tea, if I have a 1 l electric teapot (P = 1,500 We)? It takes 5 minutes to boil the water in the teapot and the electricity costs 4 CZK /1 kWh. The teapot is used twice for 5 minutes = 10 minutes = 1/6 * 1,500 We = 250 Wh = 0.25 kWh = 1 CZK You have a 2010 vacuum cleaner with the input of 1,500 We. Usually you use it once a week for an hour. In 2018 you decided to buy a new one, due to the EU regulations its output is only 750 We. Due to unexpected circumstances, you are forced to use the vacuum cleaner 5 times in a month for an hour. The price of electricity is 4 CZK /1 kWh. Are your monthly electricity expenditures lower than with the previous one? How much are they? 2010 vacuum cleaner 4 hours in a month x 1,500 We = 6,000 Wh = 6 kWh 6 kWh x 4 CZK = 24 CZK 2018 vacuum cleaner 5 hours in a month x 750 We = 3,750 Wh = 3.75 kWh 3.75 kWh x 4 CZK = 15 CZK Does it make sense to buy a new vacuum cleaner to save money on electricity?